Looking to know if copper strips can be spot-weld onto a lithium battery pack? We got answers, tips and more here! 

Can Copper Strip Be Spot-Welded on Batteries

Yes, copper can be indirectly spot-welded by using a nickel weld as a catalyst.Copper is harder to weld than nickel because it has a low electrical resistance. This lower resistance produces less of a voltage drop and therefore less heat. With the right tools and methods, however, copper can be indirectly spot-welded.&nbsp;<h2>Why is Copper Difficult To Spot Weld?</h2>Copper, being an extremely low-resistance metal, can handle much more current than nickel. Due to its low resistance, it takes a lot of current to spot-weld copper directly. Due to its low resistance, it also makes it ideal to build a battery out of copper. Copper is so good at handling current that it can handle the welding current and won't melt.&nbsp;<h3>Nickel: A Catalyst for Spot Welding Copper</h3>Given copper's inability to directly support spot welding, nickel comes into play as a catalyst to indirectly spot weld copper. When a nickel weld is performed near copper with sufficient power, the heat generated is enough to melt not only the nickel but also the copper on the other side. This process allows a bond to form throughout both metals. This technique is commonly called a <a href="https://cellsaviors.com/blog/copper-nickel-sandwich">copper-nickel sandwich</a>.&nbsp;<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;copper nickel sandwich example.jpg&quot;,&quot;filesize&quot;:79361,&quot;height&quot;:440,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/howdo6P2srOaFHqpHwBlBOEFC8EZbO1bOcMP53rM.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/howdo6P2srOaFHqpHwBlBOEFC8EZbO1bOcMP53rM.jpg&quot;,&quot;width&quot;:800}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/howdo6P2srOaFHqpHwBlBOEFC8EZbO1bOcMP53rM.jpg"><img src="https://admin.cellsaviors.com/storage/howdo6P2srOaFHqpHwBlBOEFC8EZbO1bOcMP53rM.jpg" width="800" height="440"><figcaption class="attachment__caption">copper nickel sandwich example.jpg 77.5 KB</figcaption></a></figure> Despite the challenges involved, spot welding copper has several advantages. Copper has a vastly superior conductivity compared to nickel, which results in a more efficient transfer of energy. This is why high-performance battery systems always use copper.&nbsp;<h2>What Is The Best Copper For Spot Welding?</h2>When it comes to copper thickness, 0.1-millimeter thick copper is best suited for spot welding. It is also possible to spot-weld 0.15-millimeter thick copper, but this requires highly advanced welders, robust power supplies, and a lot of experience in <a href="https://cellsaviors.com/blog/spot-weld-battery">how to spot-weld</a>. With standard equipment, even something as efficient as a K weld, difficulties arise when attempting to weld 0.15 copper. Using 0.2-millimeter copper is completely out of the question due to its thickness.<blockquote>[[ aff type=aff ~ link=https://amzn.to/3o3UKRb ~ title=`Copper Sheet .1mm` ~ image=https://admin.cellsaviors.com/storage/copper-foil-.1mm.jpg ~ description=`Best copper sheet to use for doing copper/nickel sandwich. Can be cut easily with scissors. ` ~ height=small ~ buttonText=`Check Price`&nbsp; ]]</blockquote><figure data-trix-attachment="{&quot;contentType&quot;:&quot;image&quot;,&quot;height&quot;:740,&quot;url&quot;:&quot;https://lh3.googleusercontent.com/a90apItjxDc0HAyQoM3Ekj6WHYVpiSyEqk1c-7VxIKWHxXMnOEwRKn96udq1TAZTwQxgXurWP82eR4TVsXSh_33IZjuPhZmTPniXVE3Qxo_Q_8kCbo-vGTsjBJAxd0D4bmGfg6I-hI_WZ0jep9zICFQ&quot;,&quot;width&quot;:624}" data-trix-content-type="image" class="attachment attachment--preview"><img src="https://lh3.googleusercontent.com/a90apItjxDc0HAyQoM3Ekj6WHYVpiSyEqk1c-7VxIKWHxXMnOEwRKn96udq1TAZTwQxgXurWP82eR4TVsXSh_33IZjuPhZmTPniXVE3Qxo_Q_8kCbo-vGTsjBJAxd0D4bmGfg6I-hI_WZ0jep9zICFQ" width="624" height="740"><figcaption class="attachment__caption"></figcaption></figure><h2>What is The Thickest Copper You Can Spot Weld?</h2>When it comes to spot welding copper, the thickness of the material plays a crucial role in the success of the operation. The maximum thickness that can be effectively spot welded using a kWeld, one of the<a href="https://cellsaviors.com/blog/best-spot-welders"> best spot welders</a>, is typically around 0.15 millimeters. However, achieving this thickness requires optimal conditions, including a high-quality <a href="https://cellsaviors.com/blog/diy-bench-power-supply">bench power supply</a> and extremely sharp welding probes.The power supply must be capable of delivering the amps required for spot welding copper that thick, which is a highly conductive material. The sharpness of the probes is also critical, as it ensures the current is concentrated at the spot of the weld, enabling the welding of thicker materials.In more realistic conditions, the maximum thickness for spot welding copper is usually around 0.1 millimeters. This is due to the challenges presented by the high thermal and electrical conductivity of copper. Despite these limitations, there are techniques to work around this issue. One such method involves layering, where multiple welds are performed one on top of the other.&nbsp;This technique allows for the creation of series connections with metals that are traditionally too thick to be spot welded. While the thickness of the material that can be welded in a single operation is limited, performing multiple welds can theoretically overcome these limitations. This opens up possibilities for using a wider range of materials, including thicker copper, when it comes to <a href="https://cellsaviors.com/blog/building-a-battery-pack-from-18650-cells">building lithium battery packs</a>.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;battery pack built with copper nickel sandwich spot welds.jpg&quot;,&quot;filesize&quot;:71169,&quot;height&quot;:246,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/NkxpcXT96J9SJZG6IgZqbXnhmTgRDTLttWWFXd72.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/NkxpcXT96J9SJZG6IgZqbXnhmTgRDTLttWWFXd72.jpg&quot;,&quot;width&quot;:432}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/NkxpcXT96J9SJZG6IgZqbXnhmTgRDTLttWWFXd72.jpg"><img src="https://admin.cellsaviors.com/storage/NkxpcXT96J9SJZG6IgZqbXnhmTgRDTLttWWFXd72.jpg" width="432" height="246"><figcaption class="attachment__caption">battery pack built with copper nickel sandwich spot welds.jpg 69.5 KB</figcaption></a></figure><h2>Safety Precautions in Spot Welding Copper</h2>When spot welding copper, it’s crucial to take several safety precautions due to the unique challenges this metal presents. The high temperatures produced during the process generate significantly more fumes and smoke than nickel welding, which can be harmful if inhaled. In addition to dealing with the safety concerns of spot-welding copper, you should also be following the <a href="https://cellsaviors.com/blog/lithium-cell-battery-safety">best safety practices with lithium-ion batteries</a>.&nbsp;Ventilation: Ensure you have adequate ventilation in your workspace to avoid exposure to these harmful fumes and gasses. Treat copper welding the same way you would soldering in terms of ventilation. An extraction fan or a fume extraction system can be beneficial in maintaining a safe environment.Power Source Safety: Copper welding requires a high amount of electrical energy. Make sure your power source is capable of handling the load without risk of overheating or short-circuiting. Regularly inspect your power source for any signs of damage or wear.Heat Management: The welding probes can become extremely hot during the process. Either wear heat-resistant gloves to protect your hands or wrap your welding probes with some sort of thermally insulative material.&nbsp;<h2>So Why Batteries Spot-welded With Nickel Over Copper?</h2>Batteries are made with nickel because it is easier to spot weld and has excellent anti-corrosive properties. These two factors make it the go <a href="https://cellsaviors.com/blog/battery-pack-conductors">conductor used when building battery packs</a>. Nickel is nowhere near the ideal material for battery production. It has a much higher resistance than copper, aluminum, or even brass. This means that for the same amount of current, nickel will always run hotter and be less efficient.&nbsp;<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/png&quot;,&quot;filename&quot;:&quot;metal conductivity chart.png&quot;,&quot;filesize&quot;:76973,&quot;height&quot;:450,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/fLJVPWyhtpZUL24VYaBmL248I294jLJIUNWEuVcW.png&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/fLJVPWyhtpZUL24VYaBmL248I294jLJIUNWEuVcW.png&quot;,&quot;width&quot;:270}" data-trix-content-type="image/png" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--png"><a href="https://admin.cellsaviors.com/storage/fLJVPWyhtpZUL24VYaBmL248I294jLJIUNWEuVcW.png"><img src="https://admin.cellsaviors.com/storage/fLJVPWyhtpZUL24VYaBmL248I294jLJIUNWEuVcW.png" width="270" height="450"><figcaption class="attachment__caption">metal conductivity chart.png 75.17 KB</figcaption></a></figure>Spot welding operates by channeling a high amount of power through a small area. For materials like nickel that have a high resistance, this produces a very large voltage drop that results in a large amount of power dissipated into the weld area as heat.&nbsp;This heat is intense enough to be able to liquefy several layers of metal. This intense heat, however, is highly localized and doesn’t make its way into the cell chemistry.

Can you spot weld copper?

Looking to boost 12v up to 24v? Luckily you have some easy to follow options, we present them here.

How to Increase 12 Volts to 24 Volts 

To increase 12 volts to 24 volts, you will need to use a boost converter or a fixed-voltage step-up regulator, which is basically just a boost converter set to a specific voltage and usually installed in some sort of housing.&nbsp;<h2>12v to 24v Through A Boost Converter</h2>In the world of electronics, one of the core tasks often involves altering voltages to meet specific needs. To achieve this with Direct Current (DC), a boost converter is your best bet. This special kind of regulator applies precise control logic, high-speed signal manipulation, and an intricate understanding of electronics to amplify DC voltages.<h2>Boost or Step-Up Converter for Increasing 12v to 24v</h2>For straightforward operations where the task is to power basic 24-volt devices, a typical boost converter will suffice. However, if the requirement is a specific conversion from 12 volts to 24 volts, you may opt for a step-up converter. This device is essentially a pre-configured boost converter. It offers a fixed voltage output and a range voltage input, usually encased with attached wires for convenience.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;12v-24v-step-up-converter.jpg&quot;,&quot;filesize&quot;:68750,&quot;height&quot;:256,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/ERanui4FoFTLDhIS5j2g7JzFK6ug71ue3jhOgBZs.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/ERanui4FoFTLDhIS5j2g7JzFK6ug71ue3jhOgBZs.jpg&quot;,&quot;width&quot;:440}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/ERanui4FoFTLDhIS5j2g7JzFK6ug71ue3jhOgBZs.jpg"><img src="https://admin.cellsaviors.com/storage/ERanui4FoFTLDhIS5j2g7JzFK6ug71ue3jhOgBZs.jpg" width="440" height="256"><figcaption class="attachment__caption">12v-24v-step-up-converter.jpg 67.14 KB</figcaption></a></figure><h2>Accounting for Current Requirements While Increasing Voltage</h2>It's imperative to ensure that the chosen boost converter or step-up converter can support the required current. If you have a 12 to 24-volt boost converter running at 5 amps on the output, it'll draw double—10 amps—from the input. So make sure you <a href="https://cellsaviors.com/blog/how-to-size-wire-fuses-and-nickel-strip-for-a-lithium-battery-pack">size wires and fuses</a> to account for the doubling of current on the input side. This phenomenon results from the essential principle that when voltage increases on the output side, the current correspondingly amplifies on the input side.&nbsp;The opposite occurs when <a href="https://cellsaviors.com/blog/24v-reduced-to-12v">reducing 24v to 12v</a> you will experience half the voltage on the input side when compared to the output side.Make sure you keep in mind the current limits of your boost converter or step-up converter. This limit applies to the input primarily, as the input will always carry a higher current than the output. If the converter indicates a 10-amp limit, do not expect it to deliver 10 amps output; that 10-amp limit usually applies to the input, unless specified otherwise by the manufacturer.<blockquote>[[ aff type=aff ~ link=https://amzn.to/3ZkSAuB ~ title=`12v to 24v Boost Converter` ~ image=https://admin.cellsaviors.com/storage/12-24v-boost-converter.jpg ~ description=`Easy to use 12v to 24v boost converter. A few available amperage ratings from this seller.` ~ height=small ~ buttonText=`Check Price`&nbsp; ]]</blockquote><h2>Ensuring Adequate Capacity and Cooling When Increasing 12v to 24v</h2>When setting up a boost converter or step-up converter, it's always a good idea to avoid pushing the device to its absolute limits. For example, if your load requires 10 amps, it's advisable to invest in a converter rated for at least 15 amps.Many converters available in the market, including those listed on platforms like Amazon, require active cooling in order to meet their advertised ratings. So, a converter that claims a 10-amp capacity might realistically handle only 5 or 6 amps without a fan. So, it’s important to consider this factor and oversize the converter accordingly. Doing this will prevent overheating and extend the lifespan of your converter.<h2>How To Increase 12 Volts To 24 Volts To Charge A Battery</h2>When considering the specific goal of using a 12-volt source to charge a 24-volt lithium-ion battery, there are additional important considerations. This process necessitates more than a simple voltage increase. You also have to maintain control over the charging current, ensuring it's regulated to meet the battery's specifications.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;12v-24v-step-up-charger.jpg&quot;,&quot;filesize&quot;:98968,&quot;height&quot;:323,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/QmydQmtyr8vfPoORsPR8N3mkqDUFjvFedcHBy9oF.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/QmydQmtyr8vfPoORsPR8N3mkqDUFjvFedcHBy9oF.jpg&quot;,&quot;width&quot;:556}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/QmydQmtyr8vfPoORsPR8N3mkqDUFjvFedcHBy9oF.jpg"><img src="https://admin.cellsaviors.com/storage/QmydQmtyr8vfPoORsPR8N3mkqDUFjvFedcHBy9oF.jpg" width="556" height="323"><figcaption class="attachment__caption">12v-24v-step-up-charger.jpg 96.65 KB</figcaption></a></figure><h3>Understanding Cell Groupings and Voltage Requirements</h3>To charge a 24-volt lithium-ion battery effectively, you first need to understand how the cells within the battery are arranged. Most commonly, these batteries consist of seven-cell groups in series. Each group needs to be charged to a voltage of 4.2 volts. Multiply the 4.2 volts per group by the seven groups and you'll arrive at the total required charge voltage: 29.4 volts. For an LFP battery, the math would be 3.6v multiplied by eight to give you 28.8v.&nbsp;<blockquote>[[ aff type=aff ~ link=https://amzn.to/3y4sDDc ~ title=`Boost Converter` ~ image=https://admin.cellsaviors.com/storage/81c4URq5jjL._AC_SX679_.jpg ~ description=`Input voltage: DC 8-60V; Output voltage: DC 10-120V; Input current: 0-15A; Output current: 0-15A.` ~ height=large ~ buttonText=Check Price``&nbsp; ]]</blockquote><h3>Why a Constant Current Boost Converter is Needed</h3>Merely stepping up the voltage to this level isn't enough for proper charging, however. A constant current boost converter is required. Unlike a simple fixed voltage step-up converter, this device can ensure that the charging current is controlled and constant during the initial phase of charging. If you are looking to <a href="https://cellsaviors.com/blog/lithium-charger-diy">build a DIY lithium battery charger</a> it is important to make sure the boost converter mentions it supports constant current and constant voltage (CC/CV).Once the voltage reaches the level calculated earlier (4.2 volts per cell group), the charger switches to a 'constant voltage' phase. Now, the voltage is kept steady, while the current is allowed to decrease gradually. This two-stage charging approach is crucial to ensure the battery is charged safely and efficiently and to maximize its lifespan.Simply using a fixed voltage step-up converter could risk overcharging or even damaging the battery if it fails to regulate the current properly during the initial charging stage.

How to Increase 12 volts to 24 volts

Learning how to calculate watt-hours to amp-hours and how to compare those numbers will help determine true battery capacity.

How to Calculate And Compare Watt Hours to Amp hours

Watt hours (Wh) can be converted to Amp-hours (Ah) using the formula Ah = Wh / Voltage, where voltage refers to the nominal voltage of the battery.<h2>Understanding Watt Hours and Amp Hours</h2>Watt hours (Wh) and amp hours (Ah) are two important units of measurement in the electrical world, providing insights into energy storage and consumption. Converting between these two to <a href="https://cellsaviors.com/blog/battery-capacity-test">determine battery pack capacity</a> is straightforward and can be done using Ohm's law. If, for example, your project needs a 1,200-watt-hour battery, the number of amp hours can be deduced by dividing the watt-hours by the battery's nominal voltage. So, if you're building a 12-volt battery, a hundred amp hours of cells are needed to deliver 1,200-watt hours.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;Battery Label Showing Wh and Ah capacities.jpg&quot;,&quot;filesize&quot;:71549,&quot;height&quot;:476,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/OJeypxZK4uBdXgTMcpkAMEzWVxsumvoTnSBPGepG.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/OJeypxZK4uBdXgTMcpkAMEzWVxsumvoTnSBPGepG.jpg&quot;,&quot;width&quot;:450}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/OJeypxZK4uBdXgTMcpkAMEzWVxsumvoTnSBPGepG.jpg"><img src="https://admin.cellsaviors.com/storage/OJeypxZK4uBdXgTMcpkAMEzWVxsumvoTnSBPGepG.jpg" width="450" height="476"><figcaption class="attachment__caption">Battery Label Showing Wh and Ah capacities.jpg 69.87 KB</figcaption></a></figure><h2>Getting Practical: From Theory to Application</h2>Applying these concepts to real-life scenarios makes the calculation more tangible. If your battery cell has a capacity that's already known, this information can help determine the number of cells needed to reach the desired amp hours. As an example, if you're using 3 Ah cells and need to reach a target of 100 Ah, 34 cells would need to be <a href="https://cellsaviors.com/blog/parallel-lithium-batteries">connected in parallel</a>. To achieve 12 volts, at least three cell groups <a href="https://cellsaviors.com/blog/series-lithium-batteries">connected in series</a> are necessary, meaning 102 cells would be required for the project.&nbsp; It’s also important to consider that the nominal voltage of a 3S NMC lithium-ion battery is actually 11.1 volts. So, 102 Ah will actually provide 1132.2-watt hours of energy.<h2>How To Convert Watt Hours To Amp Hours</h2>Here are a few more examples. Let's say you have a 48-volt electric bike battery that can store 500 watt-hours of energy. If you want to find out the Amp-hours (Ah) of the battery, you would use the formula Ah = Wh/Voltage.Ah = 500Wh / 48V = 10.42AhSo, the 500Wh battery is equivalent to a 10.42Ah battery at 48 volts.Now, consider a 12-volt RV battery that has a capacity of 100 amp-hours. To find the watt-hours stored in this battery, you would use the formula Wh = Ah * Voltage.Wh = 100Ah * 12V = 1200WhSo, a 12V 100Ah battery can store 1200Wh of energy.<h3>Different Voltage Levels</h3>Next, let's consider a scenario where you're trying to choose between a 24V battery system and a 48V battery system for your <a href="https://cellsaviors.com/blog/diy-powerwall">DIY powerwall project</a>, and both are rated at 100Ah. How do these options compare in terms of watt-hours?For the 24V system:Wh = 100Ah * 24V = 2400WhFor the 48V system:Wh = 100Ah * 48V = 4800WhAlthough both systems have the same Amp-hour rating, the 48V system can store twice as much energy because it operates at a higher voltage.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;amp hour to watt hour comparison.jpg&quot;,&quot;filesize&quot;:57497,&quot;height&quot;:243,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/5zTBiq0q8depBXNgO35vYvnygq1d0BtKDIEIRFyB.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/5zTBiq0q8depBXNgO35vYvnygq1d0BtKDIEIRFyB.jpg&quot;,&quot;width&quot;:500}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/5zTBiq0q8depBXNgO35vYvnygq1d0BtKDIEIRFyB.jpg"><img src="https://admin.cellsaviors.com/storage/5zTBiq0q8depBXNgO35vYvnygq1d0BtKDIEIRFyB.jpg" width="500" height="243"><figcaption class="attachment__caption">amp hour to watt hour comparison.jpg 56.15 KB</figcaption></a></figure><h2>Accounting for Efficiency and Power Loss</h2>It’s important to remember that no system is 100% efficient. Any heat generated in wires, <a href="https://cellsaviors.com/blog/battery-connectors">battery connectors</a>, or regulators equates to power loss. Incorporating an additional 10-15% into your calculations to cover these losses is prudent.Lithium-ion batteries are particularly efficient when not being charged or discharged at extreme rates, reaching efficiency levels close to 99%. Because of this, any efficiencies in your system will more than likely be due to charge and discharge regulators.&nbsp;<h2>Amp Hours, Watt Hours, and Nominal Voltage</h2>The watt-hours rating is an estimate based on the nominal voltage over time and the current the battery can deliver. These figures are not exact, and it's vital to consider fluctuations. A 12-volt lithium-ion battery, for example, has a max charge voltage of 12.6 volts. If it's delivering 10 amps at 12.6 volts, it's providing 126 watts. Over one hour, that's 126 watt-hours; over ten hours, it's 1,260 watt-hours. However, the voltage will not remain constant throughout this period. By the third, fourth, or fifth hour of continuous 10-amp delivery, the voltage will have dropped from its original level.This is why nominal voltages are used in these calculations. The nominal voltage of a 12-volt battery is 11.4 volts. Hence, to accurately estimate the <a href="https://cellsaviors.com/blog/amp-hours-capacity">capacity of a battery pack in amp hours</a> and watt hours, it's essential to use the nominal voltage in your calculations.

Converting Watt Hours to Amp hours

In this article we go over calculating battery run time and the formula you will need to be able to calculate it.

How To Calculate 18650 Cell & Battery Run Time

18650 battery run time can be calculated by dividing the number of watt-hours in your battery by the amount of watts that your equipment needs.For example, if an air conditioner requires 556 watts to run and you have a 12V 100Ah battery, that's 12 volts x 100 Ah, which comes to 1200 watt-hours. 1200 watt hours divided by 556 watts comes to 2.16 hours of run time.&nbsp;<h2>So, How Do You Calculate 18650 Battery Run Time?</h2>Calculating the run time of a 18650 battery involves dividing the amount of energy stored in a cell by the amount of energy per hour you need to take out of it. The charging and discharging process of lithium-ion cells is nearly 100% until you start to approach the current limits of the cells.&nbsp;Device: 5W Device x 2 hours = 10 Watt-hours.Battery: 3.5Ah x 3.7 volts nominal = 12.29Formula: Battery Wh ÷ Device Wh = Device Runtime12.29 watt hours ÷ 10 watt hours =&nbsp; 1.229 hours run time&nbsp;This means that you can get a pretty accurate estimate on how long a 18650 cell or battery built with them will run, as long as you can accurately measure current and voltage. Having a good working knowledge of this can be extremely helpful, for instance, you can use this to <a href="https://cellsaviors.com/blog/powerwall-capacity-size-calculations">calculate capacity of a powerwall</a>.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;18650 cell runtime comparison.jpg&quot;,&quot;filesize&quot;:75060,&quot;height&quot;:303,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/Nk0GiaKK4O90a7IcS4xz4sXCbEq0lWeWhtoSb8k1.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/Nk0GiaKK4O90a7IcS4xz4sXCbEq0lWeWhtoSb8k1.jpg&quot;,&quot;width&quot;:462}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/Nk0GiaKK4O90a7IcS4xz4sXCbEq0lWeWhtoSb8k1.jpg"><img src="https://admin.cellsaviors.com/storage/Nk0GiaKK4O90a7IcS4xz4sXCbEq0lWeWhtoSb8k1.jpg" width="462" height="303"><figcaption class="attachment__caption">18650 cell runtime comparison.jpg 73.3 KB</figcaption></a></figure>If you are looking to measure the exact capacity of a cell to determine runtime, follow our guide on <a href="https://cellsaviors.com/blog/battery-capacity-test">measuring battery capacity</a>.<h2>Different Devices Have Different Runtimes on The Same 18650s</h2>Air conditioners are high-wattage appliances, so a window unit system can only be run for just over 2 hours with 1200 watt-hours. To put that into perspective, that same 1200 watts could recharge a cell phone around 48 times.Each charge of a cell phone will get anywhere between 6 to 10 hours of use depending on the application. This means that in the case of running a cell phone, a 12V 100Ah battery will ultimately run the equipment it's powering for 384 hours on a single charge. It's important to remember that nothing is 100% efficient. Most inverters operate at about 90 percent efficiency, so you will end up getting a little less than 2 hours of air conditioner run time.<h2>Understanding Watt-hours VS Amp-hours</h2>Watt-hours (Wh) is a measure of electrical energy and is used to describe the capacity of a battery. A battery with a higher watt-hour rating will store more energy and typically have a longer run time. The watt-hour rating, however, is almost never listed. You have to instead multiply the amp hour rating by the cell’s nominal voltage. So, if you are wondering how to calculate how many watt-hours are in a 18650, you do it like this:&nbsp; 3Ah x 3.7 volts nominal =&nbsp; 11.1 watt hours.&nbsp;Battery Capacity in Ah x Cells Nominal Voltage = Battery Watt Hours<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;amp-hour-to-watt-hour-example.jpg&quot;,&quot;filesize&quot;:58103,&quot;height&quot;:469,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/VdDY0UPEvNJpHdVUwy6ZvMyUdrsQt34riggmkF98.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/VdDY0UPEvNJpHdVUwy6ZvMyUdrsQt34riggmkF98.jpg&quot;,&quot;width&quot;:599}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/VdDY0UPEvNJpHdVUwy6ZvMyUdrsQt34riggmkF98.jpg"><img src="https://admin.cellsaviors.com/storage/VdDY0UPEvNJpHdVUwy6ZvMyUdrsQt34riggmkF98.jpg" width="599" height="469"><figcaption class="attachment__caption">amp-hour-to-watt-hour-example.jpg 56.74 KB</figcaption></a></figure>As you can see, the amount of watt-hours in a cell is related to its voltage. This is important to remember when comparing LFP and NMC cells based on amp hours. Because LFP cells have a lower voltage, it takes more amp hours to reach the same amount of watt-hours compared to an NMC cell.We did a full write-up on understanding battery capacity which compares <a href="https://cellsaviors.com/blog/amp-hours-capacity">watt hours to amp hours</a> in detail.&nbsp;Amp-hours (Ah) is a measure of electric charge and is used to represent the capacity of a battery in terms of current over time. A battery with a higher amp-hour rating will deliver more current for a longer period. If you are starting with the watt hours, this is how you find out the amp hours of the cell:&nbsp;12.95 watt hours ÷ 3.7 volts nominal = 3.5AhBattery Watt-hours ÷&nbsp; Cells Nominal Voltage = Battery Amp Hours<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;watt-hour-to-amp-hour-example.jpg&quot;,&quot;filesize&quot;:110726,&quot;height&quot;:683,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/99ox6N18RfMmi7jUc271G42BdmZgkoWOEwUdmokW.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/99ox6N18RfMmi7jUc271G42BdmZgkoWOEwUdmokW.jpg&quot;,&quot;width&quot;:598}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/99ox6N18RfMmi7jUc271G42BdmZgkoWOEwUdmokW.jpg"><img src="https://admin.cellsaviors.com/storage/99ox6N18RfMmi7jUc271G42BdmZgkoWOEwUdmokW.jpg" width="598" height="683"><figcaption class="attachment__caption">watt-hour-to-amp-hour-example.jpg 108.13 KB</figcaption></a></figure><h2>Calculating Equipment Wattage to Determine Battery Runtime</h2>To calculate the run time of a 18650 battery, you need to know the wattage of the equipment you want to power. Some devices will have the wattage listed on a label or in the user manual. If the wattage is not available, you can estimate it by multiplying the device's voltage (V) by its current draw (A). For example, a device that operates at 12 volts and draws 2 amps will have a wattage of 24 watts (12V x 2A = 24W).It’s hard to rely on the labels, though, because those are typically maximum figures. It is much better, instead, to actually measure the current and voltage of your load to determine exactly how many watts per hour it needs to run. To measure how many watts a device is using you can use a clamp meter shown below.&nbsp;<blockquote>[[ aff type=aff ~ link=https://amzn.to/481zVb3 ~ title=`Digital Clamp Meter` ~ image=https://admin.cellsaviors.com/storage/clamp-meter.jpg ~ description=`Clamp meter: This multimeter can accurately measure AC/DC Current, AC/DC Voltage, Frequency or Duty Cycle, Resistance, Capacitance and also provides Diode, Continuity, and Temperature tests.` ~ height=small ~ buttonText=`Check Price`&nbsp; ]]</blockquote>Once you have the watt-hours of your battery and the wattage of your equipment, you can calculate the run time. Divide the watt-hours by the equipment wattage to determine the number of hours the battery can power the device. Using the example provided earlier:1200 watt-hours (battery capacity) ÷ 556 watts (air conditioner) = 2.16 hours of run time.You can also use the formula above to calculate how much battery capacity you need for a given load. This is helpful if you are going to <a href="https://cellsaviors.com/blog/building-a-battery-pack-from-18650-cells">build a battery pack</a> and want it to power a load for a certain amount of time. The formula would look like this:2.16 hours (run time) x 556 watts (air conditioner) = 1200 watt-hours (battery capacity)

How To Calculate 18650 Battery Run Time

Wondering if you can directly connect a solar panel to a battery? Well the short answer is NO, read more about this here.

Can You Connect A Solar Panel To A Battery Without A Charge Controller

No, you cannot connect a solar panel directly to a battery because specialized charging circuitry is required for proper battery charging and the fluctuating voltage coming in from the solar panel would be unreliable.<h2>Charging Batteries: The Role of Specialized Circuitry</h2>All batteries, lithium-ion or not, require specialized charging circuitry to ensure safe and efficient charging. Lithium-ion batteries in particular require a constant current charging phase followed by a constant voltage phase. This is not possible with any simple DC power source, even if it's generated by an AC-to-DC power supply.&nbsp;Lead acid batteries can be charged with a simple constant voltage source, but that voltage source has to be a particular level higher than the battery’s current voltage. The unstable nature of the voltage coming from a solar panel makes this impossible. Especially considering the fact that the voltage is going to drop tremendously when a load is attached.&nbsp;<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;solar charge controller.jpg&quot;,&quot;filesize&quot;:24641,&quot;height&quot;:382,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/Yj5gSZJRRAmyCqQfQn8DuDLBx6qWtf3IiPFbZah9.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/Yj5gSZJRRAmyCqQfQn8DuDLBx6qWtf3IiPFbZah9.jpg&quot;,&quot;width&quot;:466}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/Yj5gSZJRRAmyCqQfQn8DuDLBx6qWtf3IiPFbZah9.jpg"><img src="https://admin.cellsaviors.com/storage/Yj5gSZJRRAmyCqQfQn8DuDLBx6qWtf3IiPFbZah9.jpg" width="466" height="382"><figcaption class="attachment__caption">solar charge controller.jpg 24.06 KB</figcaption></a></figure><h2>Voltage Challenges in Solar Charging</h2>Most solar panels have a peak voltage of around 18 or 19 volts under optimal conditions. There are several environmental factors such as passing clouds or obstructive objects, that will cause the output voltage to drop dramatically. In addition to the dramatic changes, as the sun changes its position throughout the day, the voltage output of the panel will naturally raise and lower.These facts totally rule out the possibility of connecting a solar panel directly to a battery. The battery charging process relies on providing the battery with a voltage that is slightly higher than its current voltage. This can either be done in a simple way, such as charging a lead acid battery, or a complicated way, like <a href="https://cellsaviors.com/blog/lithium-charger-diy">charging a lithium-ion battery</a>.&nbsp;The power transferred during charging relates directly to the difference between the charge voltage and the battery voltage. So, a solar panel, with its voltage continually changing due to environmental factors, isn't at all suitable for providing consistent voltage for battery charging.<h2>Solar Charge Controllers: The Proper Way to Connect A Solar Panel To A Battery</h2>The correct and most efficient way to connect a solar panel to a battery is by using a solar charge controller. These devices are designed so that their outputs can handle the specific voltage requirements of different types of batteries, ensuring a steady and appropriate flow of charge. A solar charge controller’s input, however, is designed to work with the constantly changing voltage coming in from a solar panel.&nbsp;The charge controller can be thought of as a voltage stabilizer that can take in an unstable voltage from the sun and output a stable voltage to a battery.&nbsp;<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;mppt.jpg&quot;,&quot;filesize&quot;:30611,&quot;height&quot;:477,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/xfSyRupEDyRR87lqaMUN8hc7tOHF1DZDuFdmFTRd.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/xfSyRupEDyRR87lqaMUN8hc7tOHF1DZDuFdmFTRd.jpg&quot;,&quot;width&quot;:522}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/xfSyRupEDyRR87lqaMUN8hc7tOHF1DZDuFdmFTRd.jpg"><img src="https://admin.cellsaviors.com/storage/xfSyRupEDyRR87lqaMUN8hc7tOHF1DZDuFdmFTRd.jpg" width="522" height="477"><figcaption class="attachment__caption">mppt.jpg 29.89 KB</figcaption></a></figure><h2>Types of Solar Charge Controllers: PWM and MPPT</h2>There are <a href="https://cellsaviors.com/blog/mppt-pwm-solar-charge-controller">two main types of solar charge controllers</a>: Pulse Width Modulation (PWM) and Maximum Power Point Tracking (MPPT). While MPPT controllers are more efficient, they are typically larger and more expensive. These controllers are best for larger solar installations where efficiency is of utmost importance.On the other hand, PWM controllers are less expensive and are generally more compact, which makes them better for applications where space is at a premium. PWM solar controllers are a great, low-cost way to properly <a href="https://cellsaviors.com/blog/connect-solar-panels">connect a solar panel to a battery.</a><h2>Can You Power Anything Directly With Solar Panels? &nbsp;</h2>Yes, there are all kinds of things you can power directly with solar panels. On a bright, sunny, cloudless day, a properly mounted solar panel will always have a decent running voltage. A simple buck converter could be attached to that to level the voltage out to around 12 volts. That voltage source can be used to power all kinds of low-power electronics like phone and laptop chargers, lights, sound systems, and all kinds of other things like that.<blockquote>[[ aff type=aff ~ link=https://amzn.to/3E3qLOz ~ title=`Buck Converter DC to DC Step Down` ~ image=https://admin.cellsaviors.com/storage/81L1-6rB9OL._AC_SX679_.jpg ~ description=`The input voltage range is DC 10-65V; Output voltage range is DC 0-60V, which is adjustable and used to convert 24v to 12v 5v; Output current range is 0-12A, which is adjustable; Max output power is 720W` ~ height=large ~ buttonText=Check Price``&nbsp; ]]</blockquote>It’s not the most practical way to use solar power, but it can most certainly get the job done.&nbsp;

Can I Connect A Solar Panel Directly to A Battery?

Looking to test IR with a multimeter? We got you covered, in this article we will go over the simple steps for testing.

How to Check Internal Resistance with A Multimeter

To measure internal resistance with a multimeter, you first measure the unloaded voltage of the battery (v1), then the voltage under load (v2), and finally the resistance of the load (r1), which allows you to calculate the internal resistance using ISR = (V1 - V2)/(V2/R1).Internal resistance refers to a battery's inherent resistance to the flow of electric current. No system is 100% efficient, and this applies to batteries as well. Inside each battery, chemical reactions take place to produce electrical energy, and this process doesn’t happen perfectly. This inefficiency results in a certain level of internal resistance and a certain amount of heat generation at a given current level.<h2>Factors Influencing Internal Resistance</h2>The efficiency of a battery and its ability to transfer current is a result of its internal resistance. A battery has to carry out complex chemical reactions to be able to transfer electrical current. The speed at which these chemical reactions happen, the shape of the internal structure of the battery, and several other factors all culminate and manifest themselves as IR or internal resistance.&nbsp;A battery that is old or has been abused will likely have higher internal resistance. In such cases, the chemistry inside the battery becomes less effective at transferring current and slower to react to sudden changes. This results in an increased amount of heat per amp of current delivered thereby <a href="https://cellsaviors.com/blog/lithium-batteries-degradation">increasing the rate of degradation over time</a>.&nbsp;<h2>Measuring Internal Resistance With A Multimeter</h2>Measuring a battery's internal resistance with a multimeter is simple. All you have to do is take three measurements Here are the steps involved:<ol><li>Measure the Unloaded Voltage: Measure the voltage of the battery when it is not connected to any load. Note this voltage as V1. <figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;testing battery voltage.jpg&quot;,&quot;filesize&quot;:166526,&quot;height&quot;:465,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/HH3iVdf3GLJqK8op4aNyQT5YejOEfG6reGJD8r4x.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/HH3iVdf3GLJqK8op4aNyQT5YejOEfG6reGJD8r4x.jpg&quot;,&quot;width&quot;:609}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/HH3iVdf3GLJqK8op4aNyQT5YejOEfG6reGJD8r4x.jpg"><img src="https://admin.cellsaviors.com/storage/HH3iVdf3GLJqK8op4aNyQT5YejOEfG6reGJD8r4x.jpg" width="609" height="465"><figcaption class="attachment__caption">testing battery voltage.jpg 162.62 KB</figcaption></a></figure></li><li>Measure the Load's Resistance: Switch the multimeter to resistance and measure the resistance of the load that you are going to use to test the battery. Not this value as R1.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;test load resistor.jpg&quot;,&quot;filesize&quot;:162107,&quot;height&quot;:393,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/ShxVdWqtRiDMJvgIr1N9X1HF7ZLkj2Vcl5gJp6rH.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/ShxVdWqtRiDMJvgIr1N9X1HF7ZLkj2Vcl5gJp6rH.jpg&quot;,&quot;width&quot;:669}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/ShxVdWqtRiDMJvgIr1N9X1HF7ZLkj2Vcl5gJp6rH.jpg"><img src="https://admin.cellsaviors.com/storage/ShxVdWqtRiDMJvgIr1N9X1HF7ZLkj2Vcl5gJp6rH.jpg" width="669" height="393"><figcaption class="attachment__caption">test load resistor.jpg 158.31 KB</figcaption></a></figure></li><li>Measure the Loaded Voltage: Finally, switch the multimeter back to voltage and connect the load resistor to the battery. Quickly measure the voltage of the battery once it settles. Not this value as V2.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;measuring loaded voltage.jpg&quot;,&quot;filesize&quot;:222425,&quot;height&quot;:546,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/GEc469hRYFJlu9C0KFxkrpH7tSwY1vGR81Mq19QG.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/GEc469hRYFJlu9C0KFxkrpH7tSwY1vGR81Mq19QG.jpg&quot;,&quot;width&quot;:682}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/GEc469hRYFJlu9C0KFxkrpH7tSwY1vGR81Mq19QG.jpg"><img src="https://admin.cellsaviors.com/storage/GEc469hRYFJlu9C0KFxkrpH7tSwY1vGR81Mq19QG.jpg" width="682" height="546"><figcaption class="attachment__caption">measuring loaded voltage.jpg 217.21 KB</figcaption></a></figure></li></ol>These three values are all you need to be able to calculate the internal resistance of a batter using this formula:IR = (V1 - V2)/(V2/R1) So, for example, let's take a battery cell that is charged to 3.7 volts and place a 1 Ohm load resistor across it and see how its voltage lowers.&nbsp; IR = (3.7V - 3.6V) / (3.6V / 1 Ohm) If the unloaded voltage is 3.7, and the voltage drops to 3.6 when a 1-ohm load is attached, then that means there is .1 volts of drop for a 1-ohm load. The amount of current being transferred can be found by dividing the loaded voltage (V2) by the load current (1 Ohm) which will result in 3.6 amps of current.&nbsp;0.1V / 3.6A = 0.0278 Ohm (27.8mOhm)<h2>Why Internal Resistance Matters</h2>Knowing <a href="https://cellsaviors.com/blog/calculate-internal-resistance">how to calculate the internal resistance of a battery</a> can provide critical insights. This figure, when combined with other calculations, can provide a highly accurate estimate of the following parameters:<ol><li>Voltage Drop: How much the voltage is going to drop when the battery is used.</li><li>Heat Generation: The amount of heat the battery will generate under operation.</li><li>Power Loss: The total power loss that the battery will experience.</li><li>Efficiency: The efficiency of the battery at various currents.</li></ol>These pieces of information are critical when deciding the appropriate battery for a specific application or determining if a battery without specifications can handle a particular load.<h2>When To Use A Dedicated IR Tester</h2>If you only have to <a href="https://cellsaviors.com/blog/measure-internal-resistance">test internal resistance</a> every so often, then it's perfectly fine to use the multimeter method described in this article. If, however, you regularly have a large supply of cells or battery packs to measure, then you may want to consider buying one of those dedicated IR testers.&nbsp;<blockquote>[[ aff type=aff ~ link=https://amzn.to/3JAaOT5 ~ title=`YR1035+ 4 Line IR Tester ` ~ image=https://admin.cellsaviors.com/storage/yr1035 ir tester.jpg ~ description=`` ~ height=small ~ buttonText=`Check Price`&nbsp; ]]</blockquote>A dedicated IR tester is much faster because you only have to take one measurement. In addition, the IR reading from a standard 18650/21700 tester and charge is not accurate. So we advise going to go the dedicated IR tester route, just make sure to get more of a middle or high-priced one, rather than the cheapest possible model.&nbsp;

How Do You Check Internal Resistance With A Multimeter?

Choose the right BMS for a LiFePO4 battery can be tricky, follow along with our article to make sure you get exactly what you need.

How To Choose LiFePO4 BMS

You can calculate the BMS (Battery Management System) for Lithium Iron Phosphate (LiFePO4 or LFP) batteries by dividing the nominal voltage that your project needs by 3.25, which is the nominal voltage of LiFePO4 chemistry, and rounding to the nearest whole number.&nbsp;<h2>NMC vs LifePO4 Voltages</h2>LiFePO4 chemistry has a full charge voltage of around 3.7 volts, a nominal voltage of 3.25 volts, and a dead voltage of about 2.5 volts. NMC (Nickel Manganese Cobalt) battery chemistry that you would usually find in 18650 and 21700 cells, has a full charge voltage of 4.2 volts, a nominal voltage of 3.7 volts, and a dead voltage of around 2.5 volts.&nbsp;This means that to achieve the same overall nominal battery voltage, more LFP cells would need to be used in series. In either case, it’s the nominal voltage that you need to calculate the number of <a href="https://cellsaviors.com/blog/series-lithium-batteries">series connections</a>, and therefore, know which BMS to use.&nbsp;<h2>Calculating BMS for Different Voltages</h2>To illustrate, let's calculate the BMS for a 48-volt LiFePO4 battery. Dividing 48 by 3.25, we get 14.76. Then, we round this to the nearest whole number, which would be 15. This means that the battery requires 15 cell groups in series to achieve a 48-volt nominal voltage. You can see that we had to round, so let’s see what the actual figures for the battery will be.&nbsp;Dead Voltage: 15 Cells in Series x 2.5 volts nominal = 37.5VNominal Voltage: 15 Cells in Series x 3.25 volts nominal = 48.75VFully Charged Voltage: 15 Cells in Series x 3.7 volts nominal = 55.5VFor a 72-volt battery, we divide 72 by 3.25, which gives 22.15. Rounding down, we have 22S. If you multiply this number by the nominal voltage (3.25), you achieve a nominal voltage of 71.5 volts, quite near the intended 72 volts.Dead Voltage: 22 Cells in Series x 2.5 volts nominal = 55VNominal Voltage: 22 Cells in Series x 3.25 volts nominal = 71.5VFully Charged Voltage: 22 Cells in Series x 3.7 volts nominal = 81.4V<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;assorted LiFePO4 bms.jpg&quot;,&quot;filesize&quot;:145730,&quot;height&quot;:359,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/HUF5cfDaYjlfuew4l5ayteTObCDjqCWkXWxPhKcG.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/HUF5cfDaYjlfuew4l5ayteTObCDjqCWkXWxPhKcG.jpg&quot;,&quot;width&quot;:685}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/HUF5cfDaYjlfuew4l5ayteTObCDjqCWkXWxPhKcG.jpg"><img src="https://admin.cellsaviors.com/storage/HUF5cfDaYjlfuew4l5ayteTObCDjqCWkXWxPhKcG.jpg" width="685" height="359"><figcaption class="attachment__caption">assorted LiFePO4 bms.jpg 142.31 KB</figcaption></a></figure><h2>Additional BMS Features</h2>There is much more to a BMS than the number of cells in series that it supports. Things like temperature protection, <a href="https://cellsaviors.com/blog/powerwall-monitor">remote monitoring</a>, over-current protection, and series support also matter. These are especially important for LFP chemistry, as it cannot be charged below-freezing temperatures. Charging under freezing can lead to rapid cell damage, this can be overcome by <a href="https://cellsaviors.com/blog/lithium-batteries-warm">keeping the cells warm</a> in cold conditions.&nbsp;<h2>Does The Number of Parallel Cells Matter When Calculating LiFePO4 BMS?</h2>No. The number of <a href="https://cellsaviors.com/blog/parallel-lithium-batteries">cells in parallel</a> doesn't matter. Most BMS are hard-wired to handle a specific amount of series groups. The number of cells in parallel doesn't need to be taken into consideration because adding more cells in parallel doesn't add more series connections. Remember, when adding cells in parallel, only the amps are added. To add voltage, and therefore add more series connections, more cells need to be put in series.&nbsp;<h2>The Importance of Smart LiFePO4 BMS</h2>For large batteries with more than around 14 cells in series, a smart BMS becomes highly recommended, provided your budget and available space can accommodate it. It works in the other direction as well. For instance, if your battery configuration involves a significant number of cell groups in parallel—say, more than 10 or 15— then the same thing applies.&nbsp;These smart BMS systems are more expensive and are physically larger than their non-smart counterparts, but for setups with a lot of cells, remote monitoring becomes more of a requirement than an option.<blockquote>[[ aff type=cta ~ bg=`` ~ main=`Guided BMS Picker` ~ second=`Need help picking a Smart BMS, use the tool found at the link below to get guided to the correct LiFePO4 BMS. ` ~ btnText=`BMS Picker` ~ btnLink=`https://cellsaviors.com/bms-picker` ~ align=`center` ]]</blockquote><h2>How To Calculate LiFePO4 BMS Amperage</h2>Calculating the amperage for the BMS involves understanding the load your project will demand from the battery and the capacity of your cells. In general, the BMS should be able to handle at least the maximum current your project will draw. It is crucial to take the time to make sure you <a href="https://cellsaviors.com/blog/bms-lithium-batteries">choose the right BMS</a> for your project, picking wrong can lead to inefficiencies and possibly dangerous working conditions.&nbsp;To calculate the amperage for the BMS, first, determine your project's maximum current draw. This information can often be found in the specifications for the device or system you're powering. If your system requires, for instance, 30A, you need a BMS that can handle at least 30A.It’s important for the BMS to be able to handle potential surge currents - the brief moments when your device might draw more power than usual. A good rule of thumb is to choose a BMS that can handle 1.5 to 2 times the maximum continuous discharge rate of your battery.<h2>Selecting a LiFePO4 BMS with a Higher Amperage Rating</h2>If you're uncertain about your system's exact current draw, or if it may vary significantly, it's safer to choose a BMS with a higher amperage rating. Remember, the amp rating on a BMS is a measure of how much power it can handle, not a measure of how much power it will put out. A BMS with a higher amperage rating than your system requires will still function effectively and can provide an additional layer of protection against unexpected power surges.Note that the BMS must not only be able to handle the maximum current that your project will draw but also the maximum charging current. This becomes more important if you're using a fast charger or if your charger's current exceeds the BMS's current rating. If the BMS cannot handle the charging current, it may cause the BMS to malfunction, which can in turn damage the battery or even become a fire hazard.

How Do You Calculate Which BMS for LiFePO4?

Looking to figure out which battery chemistry is best for your project, we lay out which is best and why here!

Which Is The Best Battery Chemistry And Why?

If energy density and cost-effectiveness are the most important factors, then NMC (Nickel-Manganese-Cobalt) is the best battery chemistry, otherwise, LFP (Lithium Iron Phosphate) is the better choice because of its significantly higher cycle life.<h2>Types of Battery Chemistries</h2>There are many types of battery chemistries, but those using lithium-ion technology are generally the best. Out of those chemistries, there are many subtypes. The most popular subtypes are NMC (Nickel Manganese Cobalt) and LFP (Lithium Iron Phosphate).&nbsp;<h2>NMC: Best Power Density, Energy Density, and Cost</h2>NMC batteries have a superior energy density when compared to their LFP counterparts. The voltage characteristics of NMC cells play a significant role in their advantage. With a full charge voltage of 4.2 volts, a nominal voltage of 3.7 volts, and a dead voltage of around 2.5 to 2.6 volts, the NMC chemistry allows more voltage to be packed into a smaller space.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;nmc-lfp-la-energy-density-weight.jpg&quot;,&quot;filesize&quot;:61031,&quot;height&quot;:300,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/uiZFxpDSBREspkyBQzDUGuHXpoMj5d0EoCG8TKOd.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/uiZFxpDSBREspkyBQzDUGuHXpoMj5d0EoCG8TKOd.jpg&quot;,&quot;width&quot;:500}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/uiZFxpDSBREspkyBQzDUGuHXpoMj5d0EoCG8TKOd.jpg"><img src="https://admin.cellsaviors.com/storage/uiZFxpDSBREspkyBQzDUGuHXpoMj5d0EoCG8TKOd.jpg" width="500" height="300"><figcaption class="attachment__caption">nmc-lfp-la-energy-density-weight.jpg 59.6 KB</figcaption></a></figure>In contrast, LFP cells have a full charge voltage of just 3.7 volts and a nominal voltage of 3.25 volts. Because of this, to achieve the same voltage as an NMC battery, you need more LFP cells in series.&nbsp;Partly because of the higher voltage, NMC batteries can store more energy (watt hours) in a given space or weight compared to LFP batteries. This attribute makes NMC batteries ideal for applications where space and weight are at a premium, such as <a href="https://cellsaviors.com/personal-electric-vehicles">personal electric vehicles</a> or portable electronics.In terms of cost, NMC batteries also hold a significant advantage due to their widespread production. Mass production and higher quantities mean that NMC cells are generally cheaper to manufacture, benefiting from economies of scale, making them more cost-effective in many situations.<h2>LFP: Best Longevity and Tolerance to Temperature Changes</h2>There are, however, two important factors to consider. LFP batteries stand out for their longevity. LFP chemistry can often endure 2,000 cycles or more before any notable performance or capacity degradation occurs. This is in stark contrast to NMC batteries, which will lose a significant amount of capacity after just 500 to 800 cycles.Another great benefit of LFP chemistry is its superior tolerance to thermal changes and high temperatures. This allows them to maintain performance and capacity under thermal stresses that would be bad for NMC batteries, where in the same situation, they would see drastic reductions in performance and capacity as the temperature rises.LFP batteries do have thermal limitations, though. They can be damaged if they are charged below freezing because this will cause a large amount of lithium to be plated on the anode. Because of this, many <a href="https://cellsaviors.com/blog/best-lithium-bms">LFP Battery Management Systems (BMS)</a> include temperature sensors that prevent charging below specific thresholds to mitigate this risk.&nbsp;While LFP cells are more recently entering mainstream markets and initially may have higher costs than NMC, the total cost of ownership (TCO) of an LFP system can be lower in the long run due to their extended lifespan. This makes them a viable choice for applications where a longer cycle life is the most important factor, such as in stationary energy storage systems.&nbsp;<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;LFP cells used in powerwall.jpg&quot;,&quot;filesize&quot;:77886,&quot;height&quot;:228,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/bsEstEIkWFdThNelVu7RbkLg8qciS3tkFwPkrb9A.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/bsEstEIkWFdThNelVu7RbkLg8qciS3tkFwPkrb9A.jpg&quot;,&quot;width&quot;:508}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/bsEstEIkWFdThNelVu7RbkLg8qciS3tkFwPkrb9A.jpg"><img src="https://admin.cellsaviors.com/storage/bsEstEIkWFdThNelVu7RbkLg8qciS3tkFwPkrb9A.jpg" width="508" height="228"><figcaption class="attachment__caption">LFP cells used in powerwall.jpg 76.06 KB</figcaption></a></figure><h2>So, Which Battery Chemistry Is Best?</h2>There is no one-size-fits-all best battery chemistry. Battery technology is still developing and there is no single chemistry that has all the bases covered. For this reason, there will be certain chemistries that are better for certain applications than others. We did a more detailed dive into comparing <a href="https://cellsaviors.com/blog/lifepo4-nmc-chemistry-comparison">NMC vs. LFP chemistries</a> you can check that article out if you are interested in learning more.<h3>Best Battery Chemistry For Off-Grid Systems &amp; Powerwalls:</h3>When it comes to <a href="https://cellsaviors.com/blog/diy-powerwall">building a DIY powerwall</a> or a off-grid system, people generally go with 12, 24, and 48 volts. 12 volts is the easiest and lowest cost option, and it's often the best option for smaller systems. This is where LFP chemistry has a major advantage. With a 4S LFP battery, you don’t need any kind of regulator to run 12-volt equipment.This is because, unlike NMC chemistry, LFP cells have a nominal voltage that makes it so when you put 4 of them in series, it almost perfectly matches the voltage curve of a 12V lead acid battery (generally 14.5 to 10.5 volts), which makes it so you can hook 12-volt regulators and other high power equipment directly up to your LFP battery, where with an NMC battery, you would have to put a regulator in between to be able to use all of the power available.&nbsp;<h3>Best Battery Chemistry For Limited Spaces&nbsp;</h3>When it comes to watt hours per dollar, nothing beats NMC. NMC chemistry has one of the highest energy densities available, at around 250-watt hours per liter, which comes out to around 7000-watt hours per cubic foot. That’s a lot of energy storage in a square foot.&nbsp;So, if packing the most capacity into the smallest space is the most important thing to you, then NMC is the best battery chemistry.<h3>Best Battery Chemistry For Longevity</h3>LFP chemistry can last 4 to 6 times as many cycles as a battery based on NMC technology. This makes it so that even though LFP batteries are less energy-dense, you end up getting more overall capacity from them in comparison to NMC.The LTO chemistry has some of the highest cycle life but it has extremely low energy density. Due to how low its energy density is we don't see LTO being a viable candidate except for <a href="https://cellsaviors.com/car-audio-calculator">car audio battery</a> solutions.&nbsp;So, if you don't need the most battery capacity and the overall life is the most important thing to you, then LFP will be the best battery chemistry for you.

Which Battery Chemistry Is Best?

If you are needing to supply a lot of current you have several options that are stronger than 18650 cells.

Stronger Batteries Than 18650 Cells

Several battery types like 21700s, 26650s, 32650s, 38120s, and LiPo packs can be considered stronger than a 18650 battery, given their higher current carrying capability due to their larger size and greater capacity.<h2>Understanding Battery Strength</h2>The strength of a battery, often referring to its current carrying capacity, is a measure of the number of amps it can deliver continuously. This current carrying capacity is often presented in terms of a C rating, which is a multiple of the battery's energy capacity.To better understand C ratings, it's helpful to use a few examples. The average 18650 has a capacity of about 2.5Ah and a C rating of 3. This means that it can deliver 7.5 amps of continuous current because 2.5 times 3 is 7.5. A common-sized 21700 is 5Ah with a C rating of 3, which would be a 15 amp continuous current carrying capacity. So when <a href="https://cellsaviors.com/blog/18650-21700-best-option">comparing an 18650 to a 21700 cell</a> you can see above the 21700 cell is much stronger.<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;21700 cell vs 18650 cell stats.jpg&quot;,&quot;filesize&quot;:143664,&quot;height&quot;:448,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/w4KZ9D9OyQSSqRGPqDir96vaR82eQIIXTcT0tcM4.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/w4KZ9D9OyQSSqRGPqDir96vaR82eQIIXTcT0tcM4.jpg&quot;,&quot;width&quot;:618}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/w4KZ9D9OyQSSqRGPqDir96vaR82eQIIXTcT0tcM4.jpg"><img src="https://admin.cellsaviors.com/storage/w4KZ9D9OyQSSqRGPqDir96vaR82eQIIXTcT0tcM4.jpg" width="618" height="448"><figcaption class="attachment__caption">21700 cell vs 18650 cell stats.jpg 140.3 KB</figcaption></a></figure><h2>Beyond the 18650: Stronger Battery Cells</h2>There are several battery cells that surpass the 18650's current carrying capacity. There are 21700, 26650, and 32120s battery cells. These cells are physically larger and have a greater capacity and current carrying capability than the 18650, even if they have the same C rating. So, for this reason, these types of cells would be considered stronger than an 18650.&nbsp;There is a 21700 cell called the P45A from a company called Molicel. It uses the NMC chemistry and can do 45 amps continuously. That level of power is much, much stronger than any 18650 on the market.&nbsp;26650 cells are generally LFP chemistry and are pretty rare to find, but they are out there on the market. They are typically around 5 amp hours and can do 3 to 5 C continuously depending on the cell.&nbsp;The strongest canister cell, however, is probably <a href="https://cellsaviors.com/blog/38120-battery">Headway 38120 cells</a>. Those cells can do a staggering 200 amps of current continuously, and generally have an 8Ah capacity, meaning they can do 25C. Due to this staggering strength, these are often used in <a href="https://cellsaviors.com/car-audio-calculator">car audio battery packs</a>.&nbsp;<h3>Lipos Strongest Pouch-Based Battery</h3>Perhaps the strongest battery is a battery containing Lipo cells. Due to their larger physical size and totally different construction,&nbsp; they offer a much larger contact area in the anode and cathode interface. This characteristic enables them to deliver a significantly higher amount of current, making them much stronger than the 18650s and even other larger cells.When looking to choose between lipo-based <a href="https://cellsaviors.com/blog/pouch-or-cylindrical-cells">pouch cells or 18650 cylindrical cells</a> you need to weigh the pros and cons. For instance lipos swell, they can be easily damaged, and are just not generally safe to use. So, when looking for a battery that is stronger than an 18650, LiPo should really only be used if there is no other viable option.&nbsp;<figure data-trix-attachment="{&quot;contentType&quot;:&quot;image/jpeg&quot;,&quot;filename&quot;:&quot;cylindrical-cell-compared-lipo-pouch-cell.jpg&quot;,&quot;filesize&quot;:65109,&quot;height&quot;:246,&quot;href&quot;:&quot;https://admin.cellsaviors.com/storage/qWBO3EPxLennCNvgWAuu80U47FEIdUEwTcidcrm8.jpg&quot;,&quot;url&quot;:&quot;https://admin.cellsaviors.com/storage/qWBO3EPxLennCNvgWAuu80U47FEIdUEwTcidcrm8.jpg&quot;,&quot;width&quot;:445}" data-trix-content-type="image/jpeg" data-trix-attributes="{&quot;presentation&quot;:&quot;gallery&quot;}" class="attachment attachment--preview attachment--jpg"><a href="https://admin.cellsaviors.com/storage/qWBO3EPxLennCNvgWAuu80U47FEIdUEwTcidcrm8.jpg"><img src="https://admin.cellsaviors.com/storage/qWBO3EPxLennCNvgWAuu80U47FEIdUEwTcidcrm8.jpg" width="445" height="246"><figcaption class="attachment__caption">cylindrical-cell-compared-lipo-pouch-cell.jpg 63.58 KB</figcaption></a></figure><h2>Battery Manufacturing and Quality Impact on Strength&nbsp;</h2>When assessing the strength of a battery, manufacturing, and quality control processes come into play. High-quality cells from reputable manufacturers such as Molicel, Headway, and Samsung will generally be stronger over time than low-quality cells. In addition, high-quality, reliable cells will have the most comprehensive safety mechanisms built into their design, whereas cheaper cells could cut corners.Also, there is much more to a battery than simply the cells that are used. The connections between the cells are just as important. A battery with great cells can be built, and if the connections between the cells are too poor, you won't be able to feel the advantage from those nice cells because the voltage drop between all the junctions would be too high.&nbsp;This is one of the main reasons that low-quality batteries get hot. Heat is already coming from the cells, so if any additional heat comes from the <a href="https://cellsaviors.com/blog/battery-pack-conductors">battery conductor</a>, it starts to add up quickly.&nbsp; Another thing to consider is the wire and soldering quality. You could have a totally great battery that ends up being unreliable or low performing due to something as simple as to thin of a wire or too poor of a solder joint.&nbsp;<h2>Cell Chemistries Effect on Battery Strength</h2>The chemistry of the battery also plays a vital role in determining its strength. For example, Nickel Manganese Cobalt (NMC) batteries, such as the P45A, have a high energy density. This makes them stronger in terms of overall capacity. On the other hand, Lithium Iron Phosphate (LFP) cells are known for their longevity, so they can be considered strong in that way.&nbsp;Ultimately, however, when ‘strength’ is discussed related to battery cells, it's referring to current carrying capacity. In that regard, LFP cells win as they are able to deliver much more current than an equally sized NMC 18650.

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