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Load calculation formulae is different for Tubular and Lithium battery Inverter/UPS

Difference Between Backup Time of Lithium-Based Batteries and Tubular Lead-Acid Batteries: Formulae and Why Lithium Requires Smaller Size Batteries When designing a backup power system, understanding the backup time and capacity of batteries is crucial. Lithium-based batteries (such as Lithium-Ion or LiFePO4) and Tubular Lead-Acid batteries are two popular choices, but they differ significantly in […]

February 25, 2025/1 Comment/by Kunwer Sachdev

Su-vastika

How to calculate Load chart of a Lithium Inverter/UPS

TECHNOLOGY BLOGS

The load chart calculations become different if the INVERTER/UPS is installed with Lithium-ion or Lithium LifePO4 battery or Tubular Lead Acid battery as the TUBULAR LEAD ACID BATTERY has the capacity of C20 or C10 maximum which makes a big difference in the calculations of time. https://suvastika.com/load-calculation-formulae-is-different-for-tubular-and-lithium-battery-inverter-ups/ When calculating the load chart for an inverter with […]

February 25, 2025/0 Comments/by Kunwer Sachdev

Load calculation formulae is different for Tubular and Lithium battery Inverter/UPS

TECHNOLOGY BLOGS

February 25, 2025/1 Comment/by Kunwer Sachdev

How to calculate Load chart of a Lithium Inverter/UPS

TECHNOLOGY BLOGS

Su-vastika

February 25, 2025/0 Comments/by Kunwer Sachdev

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Load calculation formulae is different for Tubular and Lithium battery Inverter/UPS

TECHNOLOGY BLOGS

Difference Between Backup Time of Lithium-Based Batteries and Tubular Lead-Acid Batteries: Formulae and Why Lithium Requires Smaller Size Batteries

Energy Storage System (ESS) 1P - 1P ESS 10KVA

Lithium Inverter/UPS

When designing a backup power system, understanding the backup time and capacity of batteries is crucial. Lithium-based batteries (such as Lithium-Ion or LiFePO4) and Tubular Lead-Acid batteries are two popular choices, but they differ significantly in terms of performance, capacity, and size. The key differences lie in their discharge characteristics, energy density, and the formulae used to calculate their backup time. Let’s explore these differences and why lithium-based batteries require smaller sizes for the same load.

1. Backup Time Formulae for Batteries

The backup time of a battery depends on its capacity (measured in Ampere-hours, Ah) and the load (measured in Watts or Amperes). The general formula to calculate backup time is:

$Backup Time (hours) = Load (Watts) Battery Capacity (Ah) \times Battery Voltage (V) \times Efficiency$

However, the discharge rate (C-rating) of the battery plays a critical role in determining the usable capacity. This is where Lithium-based and Tubular Lead-Acid batteries differ significantly.

2. Discharge Rate and Capacity: C1 vs. C20

Tubular Lead-Acid Batteries

Tubular Lead-Acid batteries are typically rated at the C20 discharge rate, meaning their capacity is measured when discharged over 20 hours. https://suvastika.com/how-to-calculate-backup-time-in-tubular-battery-inverter/
For example, a 100Ah Tubular Lead-Acid battery can deliver 5A for 20 hours (C20 rating).
If discharged at a higher rate (e.g., C1 or 1-hour discharge), the usable capacity drops significantly due to the Peukert Effect. This effect states that the effective capacity of a Lead-Acid battery decreases as the discharge rate increases.
Formula for effective capacity at different discharge rates: $Effective Capacity = k \times ( I ) ^{n} Rated Capacity (Ah)$ Where:
- $k$ = Peukert constant (typically 1.1 to 1.3 for Lead-Acid batteries)
- $I$ = Discharge current
- $n$ = Peukert exponent (typically 1.2 to 1.3 for Lead-Acid batteries)

Lithium-Based Batteries

Lithium-based batteries are typically rated at the C1 discharge rate, meaning their capacity is measured when discharged over 1 hour.
For example, a 100Ah Lithium battery can deliver 100A for 1 hour (C1 rating).
Lithium batteries have a flat discharge curve and are less affected by the Peukert Effect. This means their usable capacity remains nearly the same even at higher discharge rates.
Formula for effective capacity: Effective $Effective Capacity Rated Capacity (Ah) ($ No significant reduction in capacity at higher discharge rates.) https://en.wikipedia.org/wiki/Lithium_iron_phosphate_battery

3. Why Lithium Requires Smaller Size Batteries for the Same Load

Higher Energy Density

Lithium-based batteries have a much higher energy density compared to Tubular Lead-Acid batteries. This means they can store more energy in a smaller physical size.
For example, a 100Ah Lithium battery is significantly smaller and lighter than a 100Ah Tubular Lead-Acid battery.

Higher Discharge Efficiency

Lithium batteries can deliver their full rated capacity even at high discharge rates (C1), whereas Tubular Lead-Acid batteries lose capacity at higher discharge rates due to the Peukert Effect.
For the same load, a Lithium battery can provide the required power with a smaller capacity because it doesn’t suffer from capacity loss at high discharge rates.

Example Calculation

Load: 1000W
System Voltage: 12V
Required Current: $12 V 1000 W = 83.33 A$

Tubular Lead-Acid Battery (C20 Rating):

To deliver 83.33A, the battery must be oversized to account for capacity loss at high discharge rates.
If the Peukert Effect reduces the effective capacity by 30%, you may need a 150Ah battery to deliver 83.33A for 1 hour.

Lithium Battery (C1 Rating):

A 100Ah Lithium battery can deliver 83.33A for 1 hour without significant capacity loss.
No need to oversize the battery.

Result

A 100Ah Lithium battery can handle the same load as a 150Ah Tubular Lead-Acid battery, making the Lithium battery smaller and more compact.

4. Advantages of Lithium-Based Batteries

The Lithium Baterry has the inbuilt Battery Management System which keep the life of the battery maintained by equalizing each cell of the battery and we can monitor all the parameters of the battery through the Iot devices and all the protection features work through the BMS FOR THE Lithium battery which is missing in the Tubular Lead Acid battery.

Smaller Size and Weight: Higher energy density allows for compact designs.
Longer Lifespan: Lithium batteries typically last 3-5 times longer than Tubular Lead-Acid batteries.
Faster Charging: Lithium batteries can be charged at a higher rate, reducing downtime.
Maintenance-Free: No need for regular watering or maintenance.
Better Performance at High Discharge Rates: No significant capacity loss at high loads.
The Most of the manufacturers rate their product in VA capacity rather then Watt capacity which doesn’t give any clarity about the wattage of the Inverter/UPS. BIS has mandated that approved BIS product has to have the wattage written on the product.
Always buy BIS approved product cgecking on the BIS site whether the product is approved by the Bureau of Indian Standards.

5. Conclusion

The backup time and capacity of a battery depend on its discharge characteristics and energy density. Tubular Lead-Acid batteries are limited by the Peukert Effect, which reduces their effective capacity at high discharge rates, necessitating larger battery sizes for the same load. In contrast, Lithium-based batteries have a flat discharge curve, higher energy density, and can deliver their full capacity even at high discharge rates (C1). This makes Lithium batteries more efficient, compact, and suitable for applications where space and weight are critical factors.

When designing a backup power system, choosing Lithium-based batteries can result in a smaller, lighter, and more efficient solution compared to Tubular Lead-Acid batteries, especially for high-power applications.

February 25, 2025/1 Comment/by Kunwer Sachdev

How to calculate Load chart of a Lithium Inverter/UPS

TECHNOLOGY BLOGS

Su-vastika

When calculating the load chart for an inverter with a Lithium Battery (which typically has a C1 rating), you need to consider the battery’s capacity, discharge rate, and the inverter’s efficiency. The Load chart will always be calculated in terms of wattage of the inverter/UPS and Energy Storage Systems. most of the players give the capacity in terms of VA which has no meaning as each company uses different VA for it’s backup and solar products. BIS has mandated for all the manufacturers to write the capacity in wattage so that customer is not taken for the ride. bureau of Indian Standard has made it mandatory for India to have the approval of BIS for each inverter/UPS model for the safety and backup purpose. The mark of BIS has to have the real wattage of the product written by approved manufacturer so that customer get the clarity. https://suvastika.com/why-should-you-choose-a-bis-certified-inverter-ups/

BIS certified UPS

Here are the key formulae and steps:

1. Battery Capacity in Watt-hours (Wh)

Lithium batteries are often rated in Ampere-hours (Ah) and Voltage (V). Convert the battery capacity to watt-hours using the formula:

$Battery Capacity (Wh) = Battery Capacity (Ah) \times Battery Voltage (V)$

Example:

Battery Capacity = 100 Ah
Battery Voltage = 24V
Battery Capacity (Wh) = 100 Ah × 24V = 2400 Wh

2. Usable Battery Capacity

Lithium batteries typically allow a Depth of Discharge (DoD) of 80-90%. Multiply the total capacity by the DoD to get the usable capacity.

$Usable Capacity (Wh) = Battery Capacity (Wh) \times DoD$

Example:

DoD = 90% (0.9)
Usable Capacity = 2400 Wh × 0.9 = 2160 Wh

3. Inverter Efficiency

Inverters are not 100% efficient. Typical efficiency is around 85-95%. Factor this into your calculations.

$Capacity (Wh) = Usable Capacity (Wh) \times Inverter Efficiency$

Example:

Inverter Efficiency = 90% (0.9)
Effective Capacity = 2160 Wh × 0.9 = 1944 Wh

4. Total Load Calculation

Calculate the total load (in watt-hours) of all appliances you want to power during a backup. Use the formula:

$Load (Wh) =\sum (Power of Appliance (W) \times Usage Time (hours))$

Example:

LED Bulb: 10W × 4 hours = 40 Wh
Fan: 50W × 4 hours = 200 Wh
TV: 100W × 2 hours = 200 Wh
Refrigerator: 200W × 8 hours = 1600 Wh
Total Load = 40 + 200 + 200 + 1600 = 2040 Wh

5. Backup Time Calculation

To calculate the backup time, divide the effective battery capacity by the total load.

$Backup Time (hours) = Total Load (Wh) Effective Capacity (Wh)$

Example:

Effective Capacity = 1944 Wh
Total Load = 2040 Wh
Backup Time = 1944 Wh ÷ 2040 Wh = 0.95 hours (57 minutes)

6. C1 Rating Consideration

Lithium batteries are often rated at C1, meaning they can deliver their rated capacity over 1 hour. If your backup time is less than 1 hour, ensure the battery can handle the higher discharge rate.

If the backup time is less than 1 hour, the battery must support a higher discharge rate (e.g., C2, C3, etc.).
Check the battery datasheet for its maximum discharge rate.

7. Inverter Sizing

Ensure the inverter can handle the total connected load (in watts) and any starting surges.

$Capacity (W) = Total Connected Load (W) \times Safety Margin (1.2-1.3)$

Example:

Total Connected Load = 10W + 50W + 100W + 200W = 360W
Safety Margin = 1.3
Inverter Capacity = 360W × 1.3 = 468W
Choose an inverter of at least 500W.

Summary of Formulae:

Battery Capacity (Wh): Battery $Battery Capacity (Wh) = Battery Capacity (Ah) \times Battery Voltage (V)$
Usable Capacity (Wh): Usable $Capacity (Wh) = Battery Capacity (Wh) \times DoD$
Effective Capacity (Wh): Effective $Capacity (Wh) = Usable Capacity (Wh) \times Inverter Efficiency$
Total Load (Wh): Total $Load (Wh) = \sum (Power of Appliance (W) \times Usage Time (hours))$
Backup Time (hours): Backup $Backup Time (hours) = Total Load (Wh) Effective Capacity (Wh)$
Inverter Capacity (W): Inverter $Capacity (W) = Total Connected Load (W) \times Safety Margin (1.2-1.3)$

Battery Capacity: 100 Ah, 24V (2400 Wh)
Usable Capacity: 2160 Wh (90% DoD)
Effective Capacity: 1944 Wh (90% inverter efficiency)
Backup Time: 0.95 hours (57 minutes)
Inverter Capacity: 500W (with safety margin)

This will help you design a system with a lithium battery and inverter for your backup needs.

Different type of loads for home use

February 25, 2025/0 Comments/by Kunwer Sachdev

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Load calculation formulae is different for Tubular and Lithium battery Inverter/UPS

How to calculate Load chart of a Lithium Inverter/UPS

Load calculation formulae is different for Tubular and Lithium battery Inverter/UPS

How to calculate Load chart of a Lithium Inverter/UPS

Full Sized Blog Element (Big Preview Pic)

Load calculation formulae is different for Tubular and Lithium battery Inverter/UPS

Difference Between Backup Time of Lithium-Based Batteries and Tubular Lead-Acid Batteries: Formulae and Why Lithium Requires Smaller Size Batteries

1. Backup Time Formulae for Batteries

2. Discharge Rate and Capacity: C1 vs. C20

Tubular Lead-Acid Batteries

Lithium-Based Batteries

3. Why Lithium Requires Smaller Size Batteries for the Same Load

Higher Energy Density

Higher Discharge Efficiency

Example Calculation

Result

4. Advantages of Lithium-Based Batteries

5. Conclusion

How to calculate Load chart of a Lithium Inverter/UPS

1. Battery Capacity in Watt-hours (Wh)

2. Usable Battery Capacity

3. Inverter Efficiency

4. Total Load Calculation

5. Backup Time Calculation

6. C1 Rating Consideration

7. Inverter Sizing

Summary of Formulae:

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Half Sized Blog Element (Single Author Style)

Half Sized Blog Element (Multi Author Style)

Full Sized Blog Element (Big Preview Pic)

Difference Between Backup Time of Lithium-Based Batteries and Tubular Lead-Acid Batteries: Formulae and Why Lithium Requires Smaller Size Batteries

1. Backup Time Formulae for Batteries

2. Discharge Rate and Capacity: C1 vs. C20

Tubular Lead-Acid Batteries

Lithium-Based Batteries

3. Why Lithium Requires Smaller Size Batteries for the Same Load

Higher Energy Density

Higher Discharge Efficiency

Example Calculation

Result

4. Advantages of Lithium-Based Batteries

5. Conclusion

1. Battery Capacity in Watt-hours (Wh)

2. Usable Battery Capacity

3. Inverter Efficiency

4. Total Load Calculation

5. Backup Time Calculation

6. C1 Rating Consideration

7. Inverter Sizing

Summary of Formulae:

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