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Changes for page 3.3 Control

Last modified by Admin on 2025/05/30 16:50
From version 8.2
edited by Admin
on 2025/01/28 16:14
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To version 4.1
edited by Admin
on 2024/12/13 11:41
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1 -Battery management systems.BMS Main 3X.3\. Configuration.WebHome
1 +drafts.BMS Main 3X.3\. Configuration.WebHome
Content
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26 26  
27 27  Each module in a battery must have a unique address. You can change the address in the battery module settings in the “Connectivity → CAN” section of the BMS Main 3 settings.
28 28  
29 -You can set up maximum number of found modules to finish initialization in corresponding section.
30 30  
31 31  === Calculation of battery parameters ===
32 32  
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40 40  
41 41  * Minimal SOC – SOC of the modular battery is assumed to be the minimum SOC among the battery modules;
42 42  * Average SOC – SOC of the modular battery is taken equal to the arithmetic average of the SOC of the battery modules;
43 -* Min-Max SOC – SOC of the modular battery is calculated based on the minimal and maximum SOC of the battery modules (optimized for maximum health);
44 -* Max-Min SOC – SOC of the modular battery is calculated based on the minimal and maximum SOC of the battery modules (optimized for maximum capacity, recommended);
42 +* Min-Max SOC – SOC of the modular battery is calculated based on the minimal and maximum SOC of the battery modules (recommended).
45 45  
46 46  Calculation of the battery state of health (SOH) is configured in the "Control → Calculation → Final SOH" section. The following battery SOH calculation methods are supported:
47 47  
48 48  * Minimal SOH – SOH of the modular battery is assumed to be the minimum SOH among the battery modules;
49 -* Average SOH – SOH of the modular battery is taken equal to the arithmetic average of the SOH of the battery modules.
50 50  
48 +Average SOH – SOH of the modular battery is taken equal to the arithmetic average of the SOH of the battery modules.
49 +
51 51  === Main contactor ===
52 52  
53 53  The BMS Main 3X device controls the main contactor. The main contactor is usually placed in the common (minus) battery line for opening the charge and discharge circuits in case of sealing of the charging or discharging contactors.
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55 55  The Main contactor algorithm supports the following modes:
56 56  
57 57  * Always on;
58 -* Automatic, when the main contactor closes by the internal charging and discharging algorithms at the same time with Precharging, Charging, Discharging and Charging/Discharging contactors.
57 +* Automatic, when the main contactor closes by the internal charging and discharging algorithms at the same time with Precharging, Charging and Discharging contactors.
59 59  
60 60  In “Always on” mode, the main contactor closes if all the following is true:
61 61  
62 62  * “Charging” contactor is open;
63 63  * “Discharging” contactor is open;
63 +
64 64  * there are no errors.
65 65  
66 66  In “Always on” mode, the main contactor opens if “Charging” and “Discharging” contactors are open and any of the following is true:
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110 110  
111 111  To change the precharge parameters, select the section “Control → Precharge”:
112 112  
113 -[[image:1738080762857-975.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="108" width="600"]]In this section:
113 +[[image:1734089664376-736.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="56" width="600"]]
114 114  
115 +In this section:
115 115  
116 116  * Precharge current threshold to close the discharging contactor – a current value to ensure that precharge process has finished and it is allowed to close the discharging contactor, A;
117 117  * Check voltages before and after contactors to finish precharging – a flag to check the voltages before and after contactors to ensure that precharge process has finished and it is allowed to close the discharging contactor;
118 -* Minimum voltage difference before and after contactors to finish precharging – a minimum voltage difference before and after contactors to ensure precharge process finished, V;
119 -* Number of precharging attempts – maximum number of precharging attempts before setting the "Precharge error";
120 -* Precharge time – a duration of closing the precharge contactor before closing the discharging contactor, millisecond;
121 -* Relaxation between attempts – a duration between precharge attempts, millisecond;
122 -* Check the power dissipated in the preacharge resistor - a flag to enable the calculation of power dissipated in precharge resistor;
123 -* Precharge resistor resistance, Ohm;
124 -* Maximum allowable power dissipated in the resistor, W;
125 -* Delay before setting the "Precharge error" when checking power, millisecond;
126 -* Delay before clearing the "Precharge error", second;
127 -* Lock the "Precharge error" – a flag to block the error until the device is restarted.
119 +* Minimum voltage difference to finish precharging – a minimum voltage difference before and after contactors to ensure precharge process finished, V.
128 128  
129 -“Precharge error” generation conditions:
130 -
131 -* the precharge current does not decrease after "Number of precharging attempts";
132 -* voltages before and after contactors are not equal after "Number of precharging attempts";
133 -* power dissipated on the precharge resistor is above the maximum value during the “Delay before setting the 'Precharge error' when checking power” time.
134 -
135 -(% class="box warningmessage" %)
136 -(((
137 -Behavior of contactors at “Precharge error” is configured in corresponding contactor settings!
138 -)))
139 -
140 140  === Charge ===
141 141  
142 142  The BMS Main 3X device manages the parallel connection of the battery modules and the connection of the battery to the charging circuit.
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159 159  1. Checking intermodular balancing currents (the duration of the check is set in the settings). If there is no current unbalance (“Current unbalance (CH)”) or errors are ignored (“Always on”), go to step 6, otherwise open all charging contactors, and go to step 1.
160 160  1. The battery modules are joined. If the “Join to charge” request is cleared or the "Charging current unbalance" error occurs, go to step 1.
161 161  
162 -The operation of** closing main charging contactor** is described in the following steps:
143 +The operation of** closing main charging contactor** is described in the following steps:
163 163  
164 164  1. The main charging contactor “Charging” is open. When the “Charge request” is received, the voltage and current unbalance errors (“Voltage unbalance (CH)”, “Current unbalance (CH)”, “Charging current unbalance”) are cleared, and the battery modules are joined, go to step 2.
165 165  1. Closing the main precharging contactor “Precharging” (optional). Go to step 3.
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412 412  
413 413  To configure the parameters for counting the number of contactor openings, select the section “Control → Load open counter”:
414 414  
415 -[[image:1734089726360-887.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="83" width="600"]]
396 +[[image:1734089726360-887.png]]
416 416  
417 417  In this section:
418 418  
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