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--- en:iot-open:hardware2:powering:batteries [2023/11/23 11:40] – [Other energy storage systems] pczekalski
+++ en:iot-open:hardware2:powering:batteries [2024/05/23 11:05] (current) – pczekalski
@@ Line 18: / Line 18: @@
   *Mobility - The batteries should be lighter to facilitate mobility.
   *Size - In some IoT applications, especially in smart health care, it is desirable to ensure that the device's size is as small as possible, and a small-sized ESS is required.
-  *Environmental sustainability - choosing the ESS in such a way as to maximise the cycle life minimises the frequency of replacing the ESS, which ensures environmental sustainability. The ESS could also be manufactured using easily disposed of materials.
+  *Environmental sustainability - choosing the ESS in such a way as to maximise the cycle life minimises the frequency of replacing the ESS, which ensures environmental sustainability. The ESS could also be manufactured using materials that are easily disposed of.
   *Scalability - choosing durable ESS ensure scalability of IoT deployments as the limitation to scalable IoT deployments is dealing with ESS-related maintenance issues.
   *Little or no energy leakage - energy leakage is a significant problem, and the ESS chosen should not have high energy leakage.
 ===== Batteries =====
-IoT devices can be powered with rechargeable and non-rechargeable batteries. The first requires a charger circuit (built-in or as an external device), while the second is suitable for ultra-low power devices that can operate on a single battery for a very long time. Devices with non-rechargeable batteries provide the user with the ability for battery replacement (mechanically); that is not always the case for IoT devices powered with rechargeable ones.
+IoT devices can be powered with rechargeable and non-rechargeable batteries. The first requires a charger circuit (built-in or as an external device), while the second is suitable for ultra-low-power devices that can operate on a single battery for a very long time. Devices with non-rechargeable batteries allow the user to replace the battery (mechanically); that is not always the case for IoT devices powered with rechargeable ones.
 Non-rechargeable batteries are available in standard sizes such as AA, AAA, C, and D and coin-size ones such as LR44 or CR2032.
@@ Line 31: / Line 31: @@
 **LiPo**\\
-Lithium Polymer battery is a subtype of the Lithium Ion. A single cell of the Lithium Polymer battery is usually in the form of a flat cuboid (figure {{ref>lipo0}}). The single cell's standard reference voltage is 3.7V. When fully charged, the cell reaches 4.2V and should never be charged over this limit. On the other hand, LiPo cells cannot be discharged below 3.3V (some to 3.0V). The discharge curve is predictable and common for both LiPo and LiIon. A sample discharge curve is present in the figure {{ref>liiondischarge}}. Thanks to it, it is possible to estimate the remaining energy.\\
+Lithium polymer battery is a subtype of lithium ions. A single cell of the Lithium Polymer battery is usually in the form of a flat cuboid (figure {{ref>lipo0}}). The single cell's standard reference voltage is 3.7V. When fully charged, the cell reaches 4.2V and should never be charged over this limit. On the other hand, LiPo cells cannot be discharged below 3.3V (some to 3.0V). The discharge curve is predictable and common for both LiPo and LiIon. A sample discharge curve is present in the figure {{ref>liiondischarge}}. Thanks to it, it is possible to estimate the remaining energy.\\
 Single-cell voltage is low for most applications, so serial-connected cell stacks (battery packs) are used. Serial connections used to be referenced with S (capital letter s). So, e.g. 3S represents a battery composed of 3 cells, connected in serial. In the case of the serial connection, the battery's voltage is the sum of each cell. Thus, 3S represents a battery of 3*3.7V=11.1V (reference) or 12.6V when fully charged and 9.9V when fully discharged.\\
 In the case of charging the serial-connected battery packs, charging requires a separate balancing of each cell and usually requires a so-called microprocessor charger. RAW battery packs composed of more than 1 cell have two terminals: main and auxiliary for load balancing (figure {{ref>lipo1}}). The connection for charging the sample 5S battery is present in figure {{ref>5Scharging}}.
@@ Line 61: / Line 61: @@
 **LiIon**\\
-Lithium Ion batteries are widely common in electronic equipment nowadays. Their physical form is similar to LiPo ones, but there are also cylindrical units. Similarly to LiPo, LiIon single cell is nominal 3.6V or 3.7V. Charging and discharging require advanced control, and all warnings mentioned above regarding charging, discharging and maintenance of the LiPo cells also apply to LiIon.\\
+Lithium Ion batteries are widely used in electronic equipment nowadays. Their physical form is similar to LiPo ones, but there are also cylindrical units. Similarly to LiPo, LiIon single cell is nominal 3.6V or 3.7V. Charging and discharging require advanced control, and all warnings mentioned above regarding charging, discharging and maintenance of the LiPo cells also apply to LiIon.\\
 The popular model for LiIon cell is the 18650 (figure {{ref>18650}}) - the number comes from its dimension: a cylinder 18mm wide and 65mm high. Typical capacity is 2000-2500mAh per single 18650 cell.
 <figure 18650>
@@ Line 69: / Line 69: @@
 Besides the 18650, other sizes are available, such as 14500 (similar to AA size battery) with a capacity of hundreds of mAh or 26650 with a capacity exceeding 10000mAh, designated for high-rate applications such as actuators.
+<note warning>LiIon and LiPo batteries are very fragile to temperature changes. Charging those batteries when too cold or hot can cause battery and device damage, fire and related explosions.</note>
+Critical applications, such as use in electric cars, involve advanced cooling and heating systems to ensure optimal battery pack performance and charging conditions.
 == BMS ==
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 Alternative energy storage systems that can be deployed to compensate for the limitations of batteries are capacitors, supercapacitors, or ultracapacitors. They can be deployed alongside batteries (hybrid deployment) and may eventually replace batteries in some IoT deployments. Some of the limitations of batteries that can be resolved with the use of capacitors, supercapacitors, or ultracapacitors are
-  *Limited cycle life - The limited cycle life requires that batteries should be replaced frequently, resulting in multiple challenges such as high and tedious maintenance costs (as it is difficult to service a vast number of IoT devices to replace or charge the batteries), degradation of the quality of service (as devices can be shut down when all the energy stored in batteries is depleted), and challenges in disposing of batteries (as vast amounts of batteries are required to be disposed of).
+  *Limited cycle life - the limited cycle life requires that batteries should be replaced frequently, resulting in multiple challenges such as high and tedious maintenance costs (as it is difficult to service a vast number of IoT devices to replace or charge the batteries), degradation of the quality of service (as devices can be shut down when all the energy stored in batteries is depleted), and challenges in disposing of batteries (as vast amounts of batteries are required to be disposed of).
   *Inability to handle peak power load demand - Small batteries are often not able to handle peak power load demands (which may result from peak communication or computing loads), which will require that the battery should be discharged at a higher C rate, which may be unhealthy or detrimental to the battery.
-  *Slow charging and discharging process - Batteries' charging and discharging speeds are relatively slow compared to the charging and discharging speeds of capacitors, supercapacitors, and ultracapacitors.
+  *Slow charging and discharging process — Batteries' charging and discharging speeds are relatively slow compared to those of capacitors, supercapacitors, and ultracapacitors.
   *Charging and discharge inefficiencies - The magnitude of the energy harvested from the ambient environment or external sources using the small energy harvesters in IoT devices is very small (in the order of a few hundred microwatts or milliwatts) to charge batteries but can effectively charge capacitors, supercapacitors, and ultracapacitors due to their high charging and discharging efficiencies.
-  *Sustainability challenges - Since batteries may be replaced regularly due to their short lifetime, there is a growing challenge on how to dispose of battery waste without causing significant environmental damage. Some of the material used to make batteries is toxic to the environment, and frequent disposal of large amounts of batteries poses a potential environmental risk.
+  *Sustainability challenges — Since batteries may be replaced regularly due to their short lifetime, there is a growing challenge of disposing of battery waste without causing significant environmental damage. Some materials used to make batteries are toxic to the environment, and frequent disposal of large amounts of batteries poses a potential environmental risk.
 There is an increase in the adoption of capacitors, supercapacitors, or ultracapacitors as alternative energy storage systems in IoT devices due to their advantages as alternative energy storage systems. Some of their advantages include:
-  *Longer cycle life - The cycle life of capacitors, supercapacitors, or ultracapacitors is far greater than that of batteries. So, there is no need to frequently replace them, reducing maintenance costs and e-waste generated by the frequently changing of batteries. Supercapacitors can reach up to one million charge/discharge cycles, eliminating the limited cycle life problems often experienced when using batteries as energy storage systems.
+  *Longer cycle life — The cycle life of capacitors, supercapacitors, or ultracapacitors is far greater than that of batteries. So, there is no need to frequently replace them, reducing maintenance costs and e-waste generated by frequently changing batteries. Supercapacitors can reach up to one million charge/discharge cycles, eliminating the limited cycle life problems often experienced when using batteries as energy storage systems.
-  *High power densities - The high power densities make it possible to charge them with small currents (since the amount of power produced by IoT energy harvesters is very small), and also, they can handle peak power load demands (the requires the delivery of relatively large power to the IoT devices).
+  *High power densities — The high power densities make it possible to charge them with small currents (since the amount of power produced by IoT energy harvesters is very small) and also handle peak power load demands (which require the delivery of relatively large power to the IoT devices).
-  *Sustainability - Since there is no need to frequently change the energy storage systems, the amount of waste produced is relatively small. The supercapacitors are also made from materials that can be easily recycled.
+  *Sustainability - Since there is no need to change the energy storage systems frequently, the amount of waste produced is relatively small. The supercapacitors are also made from materials that can be easily recycled.
   *Faster charging and discharging speeds - Capacitors, supercapacitors, and ultracapacitors can be charged relatively fast compared to batteries.
 Although using capacitors, supercapacitors, and ultracapacitors has many advantages compared to batteries, they also have limitations.
-  *Inability to store energy for long - One of the limitations of this type of energy storage system is that they do not keep power for long, resulting in the short lifetime of the IoT devices (the time required to deplete all the energy stored in the capacitors, supercapacitors, and ultracapacitors).
+  *Inability to store energy for long — One limitation of this type of energy storage system is that it does not keep power for long, resulting in the short lifetime of the IoT devices (the time required to deplete all the energy stored in the capacitors, supercapacitors, and ultracapacitors).
-  *Size and cost limitations - One possible solution to the problem of short device lifetime resulting from the quick discharge of capacitors, supercapacitors, and ultracapacitors is to increase the energy storage capacity, which will increase the size and cost of the IoT devices, which is not desirable in most IoT applications as devices are required to be as small as possible.
+  *Size and cost limitations — One possible solution to the problem of short device lifetime resulting from the quick discharge of capacitors, supercapacitors, and ultracapacitors is to increase the energy storage capacity. However, this will increase the size and cost of the IoT devices, which is not desirable in most IoT applications, as devices are required to be as small as possible.
   *Decrease in energy capacity - When a supercapacitor reaches the end of its life, its energy capacity may drop to about 70% of its original value, limiting its ability to meet the energy storage needs of IoT devices.
-  *Energy losses - They suffer from energy losses resulting from internal energy distribution and current leakage, resulting in wastage of the energy harvested and stored. The power leakage leads to low utilisation of the harvested energy, and a portion of the harvested energy leaks away instead of powering the IoT devices.
+  *Energy losses — They suffer from energy losses resulting from internal energy distribution and current leakage, which result in the wastage of the energy harvested and stored. Power leakage leads to low utilization of the harvested energy, and a portion of the harvested energy leaks away instead of powering the IoT devices.
 Unlike batteries, supercapacitors have a lower energy density but do not suffer from cyclic degradation, similar to the case with battery cells. Ceramic capacitors are often used as an energy storage system to store energy harvested by energy harvesters incorporated into IoT devices because of their low degradation, low current leakage, and expected increase in energy densities. Thus, they are an excellent candidate to be adopted as energy storage systems deployed in industrial IoT devices ((Fredrik Häggström and Jerker Delsing, "IoT Energy Storage – A Forecast", Energy Harvesting and Systems 2018; 5(3-4) )) and IoT devices in other sectors.
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   *Mechanical energy storage system - mechanical energy storage systems can convert electrical energy into mechanical energy (potential or kinetic energy), which can then be converted into electrical energy to power IoT systems later. The most popular mechanical energy storage systems include pumped hydro, flywheels, and gravity energy storage systems. Mechanical energy storage systems are simple to design, as this technology has existed for hundreds of years. One of the limitations is that they have very low energy density and are also very inefficient.
-==== Hybrid energy storage systems ====
+===== Hybrid energy storage systems =====
 The various energy storage systems that we have discussed above have their advantages and drawbacks. One possible way to exploit the advantage of some energy storage systems and eliminate the limitations imposed by some energy storage systems is to deploy more than one energy storage system. An energy storage system that consists of more than one energy storage system is called a hybrid energy storage system. The deployment of hybrid energy storage systems (more than one energy storage system) improves the overall performance of the energy storage system in terms of energy density, reliability, and the cycle life (or lifespan) of the energy storage system. It also reduces the overall cost of the energy storage system.

en/iot-open/hardware2/powering/batteries.1700739609.txt.gz · Last modified: 2023/11/23 11:40 by pczekalski