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--- en:iot-open:power_efficiency_in_iot:iot_baterry_management_systems [2018/06/07 20:44] – created Agrisnik
+++ en:iot-open:power_efficiency_in_iot:iot_baterry_management_systems [2020/07/20 12:00] (current) – external edit 127.0.0.1
@@ Line 1: / Line 1: @@
-==== IoT Battery management systems ====
+====  ====
+<box #d04a25></box>
+<box #d04a25></box>
+==== IoT Battery Management Systems ====
+<box #d04a25></box>
+<box #d04a25></box>
-The term of battery management system (BMS) refers to a structure that allows a battery pack to be kept in a safe operating area.
+The term battery management system (BMS) refers to a structure that allows a battery pack to be kept in a safe operating area.
-A relatively advanced battery management system is basically expected to provide the following functions:
+A relatively advanced battery management system is expected to provide the following functions:
-  * Keeping the battery pack between certain voltage values, preventing overcharging and discharging
+  * keeping the battery pack between specific voltage values, preventing overcharging and discharging. It is particularly important in case of use of the Lithium-based batteries (LiPo, LiIon, LiFe);
-  * To keep the battery pack within certain temperature limits and to intervene in the system to provide these limits when necessary
+  * to keep the battery pack within certain temperature limits and to intervene in the system to provide these limits when necessary;
-  * Measuring and limiting the charge and discharge current
+  * measuring and limiting the charge and discharge current;
-  * Reducing voltage imbalances between cells to increase the effective use capacity of the battery pack
+  * reducing voltage imbalances between cells to increase the productive use capacity of the battery pack;
-  * Remaining Useful Life (RUL), State of Charge (SoC) and State of Health (SoH) estimation.
+  * remaining useful life (RUL), state of charge (SoC) and state of health (SoH) estimation.
-=== Battery System Security Issues on physical layer ===
+=== Battery System Security Issues on Physical Layer ===
 The physical layer of a battery system includes the battery cells, the surrounding circuitry, and the connections with the BMS.
-The battery cells have certain limits (lower and upper voltage/current bounds) and demonstrate speciﬁc behaviour towards diﬀerent power requests.
+The battery cells have certain limits (lower and upper voltage/current bounds) and demonstrate speciﬁc behaviour towards different power requests.
 The BMS and the circuity components are responsible for monitoring the battery cells and protecting them from overvoltage, under voltage, overcurrent, overloading, and also overheating.
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 The BMS can be any system that manages the battery. As discussed, batteries are sensitive to overcharging and deep discharging because they may damage the battery,
-therefore shortening its lifetime and even causing hazardous situations. This requires the adoption of a proper BMS to maintain the states of each
+therefore shortening its lifetime and even causing hazardous situations. This requires the adoption of a proper BMS to maintain the states of each cell of the battery within its safe and reliable operating range. In addition to its primary function of battery protection, a BMS should estimate the battery status to predict the actual amount of energy that can still be delivered to the load.
-cell of the battery within its safe and reliable operating range. In addition to its primary functionality of battery protection, a BMS should estimate
-the battery status in order to predict the actual amount of energy that can still be delivered to the load.

en/iot-open/power_efficiency_in_iot/iot_baterry_management_systems.1528393469.txt.gz · Last modified: 2020/07/20 12:00 (external edit)