Changes for page 3.3 Control

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...	...	@@ -8,7 +8,7 @@
8	8
9	9	To change the common BMS settings, select the "Control → Common settings" section:
10	10
11		-[[image:1733746733473-873.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="124" width="800"]]
	11	+[[image:1740394523706-519.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="127" width="800"]]
12	12
13	13	In this section:
14	14
...	...	@@ -16,13 +16,18 @@
16	16	* Cell resistance – nominal (maximum) internal resistance of the cell, Ohm;
17	17	* Relax time (after charging) – a relaxation time after charging, second;
18	18	* Relax time (atfer discharging) – the relaxation time after discharging, second;
19		-* Number of cycles – a number of charge-discharge cycles;
20	20	* Reset parameters– a command to reset cells state of charge, capacity, and resistance.
21	21
22		-The values “Capacity”, “Resistance”, “Cycles” are used to calculate the SOC of cells and the battery.
	21	+The values “Capacity” and “Resistance” are used to calculate the SOC of cells and the battery.
23	23
24	24	The values of “Relax time” are used to determine the state of the battery. If the battery is in a state of relaxation, the system recalculates the voltage on the cells to the state of charge of the battery.
25	25
	25	+The “Reset parameters” will reset:
	26	+
	27	+* state of charge (new cell SOC values will be calculated based on cell voltage and “Uocv (open-circuit voltage) table”: in the “Control → SOC estimation” section);
	28	+* cell resistance to “Cell resistance” value;
	29	+* battery capacity to “Cell capacity” value.
	30	+
26	26	The “Reset parameters” command is used for starting-up and adjustment of the battery.
27	27
28	28	=== SOC estimation ===
...	...	@@ -44,14 +44,14 @@
44	44	* Current and voltage (simplified);
45	45	* Current and voltage (enhanced);
46	46
47		-The SOC calculation algorithm for voltage calculates cells SOC based on the tabular dependence Uocv = Uocv(SOC, t °C).
	52	+The **“Voltage”** SOC calculation algorithm calculates cells SOC based on the tabular dependence Uocv = Uocv(SOC, t °C).
48	48
49		-The SOC calculation algorithm “Current and voltage (simplified)” works as follows:
	54	+The **“Current and voltage (simplified)”** SOC calculation algorithm works as follows:
50	50
51	51	* if I = 0, the battery is in a state of relaxation and the cell voltage Uocv is outside the [U,,ocv[point 1],,; U,,ocv[point 2],,], the SOC calculation based on the tabular dependence Uocv = Uocv(SOC, t °C);
52	52	* in any other cases, the SOC value is proportional to the charge (coulomb) passed through the battery (current time integral).
53	53
54		-The SOC calculation algorithm “Current and voltage (enhanced)” differs from the simplified algorithm by online correction of effective capacitance. When using this algorithm, it is necessary to fine tune the tabular dependence Uocv = Uocv (SOC, t °C).
	59	+The **“Current and voltage (enhanced)” **SOC calculation algorithm differs from the simplified algorithm by online correction of effective capacitance. When using this algorithm, it is necessary to fine tune the tabular dependence Uocv = Uocv (SOC, t °C).
55	55
56	56	To change the algorithm for calculating the Final SOC, select the "Control → SOC estimation → Final SOC" section:
57	57
...	...	@@ -60,32 +60,22 @@
60	60	The following battery Final SOC calculation methods are supported:
61	61
62	62	* Minimal SOC – SOC of the modular battery is assumed to be the minimum SOC among the battery modules;
63		-* Average SOC – SOC of the modular battery is taken equal to the arithmetic average of the SOC of the battery modules.
	68	+* Average SOC – SOC of the modular battery is taken equal to the arithmetic average of the SOC of the battery modules;
	69	+* Min-Max SOC – the battery SOC is calculated based on the minimum and maximum SOC of the cells. Final SOC will be a) 100% if any cell has 100% SOC, b) 0% if any cell has 0% SOC;
	70	+* Max-Min SOC – the battery SOC is calculated based on the minimum and maximum SOC of the cells. Final SOC will be a) 100% if all cells have 100% SOC, b) 0% if all cells have 0% SOC.
64	64
65		-To change other settings of SOC estimation, select the "Control → SOC estimation” section:
	72	+Other parameters:
66	66
67		-[[image:1733746733479-261.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="165" width="800"]]
68		-
69		-In this section:
70		-
71	71	* Scale the final SOC – a flag to scale the battery SOC by the following values;
72		-* SOC corresponding to 0% – battery SOC that sets to be 0%;
73		-* SOC corresponding to 100% – battery SOC that sets to be 100%.
	75	+* SOC corresponding to 0% – the battery SOC that sets to be 0%;
	76	+* SOC corresponding to 100% – the battery SOC that sets to be 100%.
74	74	* Uocv (open-circuit voltage) table – the dependence of the cell open circuit voltage Uocv on SOC and the cell temperature (selected for specific batteries);
75		-
76		-[[image:1733746733480-919.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="484" width="800"]]
77		-
78		-* Linear zone: point 1 – starting point of the linear zone of Uocv dependence;
79		-* Linear zone: point 2 – ending point of the linear zone of Uocv dependence;
	78	+* Linear zone - linear zone of the Uocv = Uocv(SOC, t°C) dependency, inside which the cell voltage changes insignificantly:
	79	+** Linear zone: point 1 – starting point of the Uocv linear zone;
	80	+** Linear zone: point 2 – ending point of the Uocv linear zone;
80	80	* Coulomb counting correction (temperature) – the dependence of battery capacity on temperature;
81		-
82		-[[image:1733746733481-286.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="160" width="800"]]
83		-
84	84	* Coulomb counting correction (cycles) – the dependence of battery capacity on the number of charge-discharge cycles.
85	85
86		-[[image:1733746733482-538.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="161" width="800"]]
87		-
88		-
89	89	=== SOC correction ===
90	90
91	91	The BMS Mini device can recalculate the battery SOC after long-term storage or after long-term working in the case when the battery was not charged fully or discharged totally. Recalculation is done based on the tabular dependency Uocv = Uocv (SOC, t) (see [[SOC estimation>>doc:||anchor="HSOCestimation"]]).
...	...	@@ -107,18 +107,26 @@
107	107
108	108	Calculation of the resistance of cells is carried out in two ways. The first method is used when the battery passes from a relaxation state to a charge or discharge state, wherein the cell resistance value
109	109
110		-R = (U-U,,ocv,,) / I,,stable,,,
	105	+{{formula fontSize="SMALL" imageType="PNG"}}
	106	+R = \frac{U-U_{ocv}}{I_{stable}}
	107	+{{/formula}}
111	111
112	112	where U is the cell voltage measured in the charge or discharge state, V; U,,ocv,, is the cell voltage measured in the state of relaxation (before switching to the state of charge or discharge); I,,stable,, – stabilized current through the cell in the state of charge or discharge.
113	113
114	114	The second method is used for a stepwise change in the current through the cell, while the value of the cell resistance:
115	115
116		-R = (U,,2,,-U,,1,,) / (I,,stable2,,-I,,stable1,,) provided that | I,,stable2,,-I,,stable1,, | > 0.2 × Q,,max,,
	113	+{{formula fontSize="SMALL"}}
	114	+R = \frac{U_2-U_1}{I_{stable2}-I_{stable1}}
	115	+{{/formula}}
117	117
118		-(Q,,max,, is the maximum cell capacity),
	117	+provided that
119	119
120		-where U,,2,, is the voltage on the cell at the moment when the stabilized current I,,stable2,, is flowing through it; U,,1,, – the voltage on the cell at the moment when the stabilized current I,,stable1,, flowing through it.
	119	+{{formula fontSize="SMALL"}}
	120	+| I_{stable2}-I_{stable1} | > 0.2 × Qmax
	121	+{{/formula}}
121	121
	123	+where Q,,max,, — the maximum cell capacity,U,,2,, — voltage on the cell at the moment when the stabilized current I,,stable2,, is flowing through it; U,,1,, — the voltage on the cell at the moment when the stabilized current I,,stable1,, flowing through it.
	124	+
122	122	The stabilized current I,,stable,, = I, if during the stabilization time the instantaneous current I is in the range from 0.95 × I to 1.05 × I.
123	123
124	124	To change parameters of the algorithm for calculating the cell resistance, select the "Control → Resistance estimation" section:
...	...	@@ -135,6 +135,62 @@
135	135
136	136	The calculated resistance is accepted by the system as valid (and therefore updated) if its value is in the range from Resistance/2 to “Maximum resistance factor” × Resistance, where "Resistance" is the nominal resistance of the cell (see [[Common settings>>doc:||anchor="HCommonsettings"]]). If the calculated resistance value is greater than the value (Maximum resistance factor × Resistance), the updated resistance value will be equal to the value (Maximum resistance factor × Resistance).
137	137
	141	+=== Low SOC (signal) ===
	142	+
	143	+To change the parameters of the generation a signal about low battery level, select the "Control → Low SOC (signal)" section:
	144	+
	145	+[[image:1740396460923-423.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="141" width="800"]]
	146	+
	147	+In this section:
	148	+
	149	+* Enable – a flag to enable signal generation;
	150	+* Minimum SOC, %;
	151	+* Tolerant SOC, %;
	152	+* Delay before setting the signal, second;
	153	+* Delay before clearing the signal, second;
	154	+* Lock – lock the signal until the device is reset.
	155	+
	156	+Signal generation conditions:
	157	+
	158	+* the battery SOC is less than the “Minimum SOC” value during the “Delay before setting the signal” time.
	159	+
	160	+Conditions for clearing the signal:
	161	+
	162	+* the battery SOC is greater than the “Tolerant SOC” during the “Delay before clearing the signal” time.
	163	+
	164	+(% class="box infomessage" %)
	165	+(((
	166	+The "Low SOC signal" is indicative and can be output to a discrete output or a power switch.
	167	+)))
	168	+
	169	+=== High charging current (signal) ===
	170	+
	171	+To change the parameters of the generation high-current signal, select the "Control → High charging current (signal)" section:
	172	+
	173	+[[image:1740396996935-403.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="144" width="800"]]
	174	+
	175	+In this section:
	176	+
	177	+* Enable – a flag to enable signal generation;
	178	+* Maximum charging current, А;
	179	+* Tolerant charging current, А;
	180	+* Delay before setting the signal, second;
	181	+* Delay before clearing the signal, second;
	182	+* Lock – lock the signal until the device is reset.
	183	+
	184	+Signal generation conditions:
	185	+
	186	+* the measured current is greater than the “Maximum charging current” value during the “Delay before setting the signal” time.
	187	+
	188	+Conditions for clearing the signal:
	189	+
	190	+* the measured current is less than the “Tolerant charging current” value during the “Delay before clearing the signal” time.
	191	+
	192	+(% class="box infomessage" %)
	193	+(((
	194	+The "High charging current" signal is indicative and can be output to a discrete output or a power switch.
	195	+)))
	196	+
138	138	=== Charge map ===
139	139
140	140	The BMS Mini device calculates maximum allowable charge current values in respect to SOC, battery temperature, contactor temperature and cell voltage.
...	...	@@ -143,31 +143,25 @@
143	143
144	144	To configure parameters for determining the charge current limit, select the "Control → Charge map" section:
145	145
146		-[[image:1733746766504-864.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="138" width="800"]]
147		-
	205	+[[image:1740397188247-315.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="179" width="800"]]
148	148	In this section:
149	149
150	150	* Enable – a flag to start calculation of the charge current limit;
151		-* Maximum charge current – a maximum allowable value of the charge current (under normal conditions):
152		-* Option 1: Limit charge current by the battery SOC and temperature – a flag to enable correction of maximum allowable charging current Kcs depending on SOC and battery temperature;
	209	+* Maximum charge current – a maximum allowable value of the charge current (under normal conditions), A;
	210	+* Rate of change – a rate of change the current limit to a new value (0 is for immediate change), A/s;
	211	+* Option 1: Limit charge current by the battery SOC and temperature – a flag to enable correction of maximum allowable charging current** Kcs** depending on SOC and battery temperature;
153	153	* Option 1: SOC x Temperature x Factor – the dependence of the correction factor on SOC and battery temperature;
154		-
155		-[[image:1733746766506-660.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="196" width="800"]]
156		-
157		-* Option 2: Limit charge current by the contactor temperature – a flag to enable correction of maximum allowable charging current Kcc depending on contactor temperature;
	213	+* Option 2: Limit charge current by the contactor temperature – a flag to enable correction of maximum allowable charging current **Kcc** depending on contactor temperature;
158	158	* Option 2: Contactor temperature x Factor – the dependence of the correction factor on SOC and contactor temperature;
	215	+* Option 3: Limit charge current by the maximum cell voltage - a flag to enable correction of maximum allowable charging current **Kcv** depending on maximum cell voltage;
	216	+* Option 3: Cell voltage x Factor – the dependence of the correction factor on maximum cell voltage;
	217	+* Option 4: Limit charge current by the cell temperature - a flag to enable correction of maximum allowable charging current **Kct** depending on maximum cell temperature;
	218	+* Option 4: Cell temperature x Factor – the dependence of the correction factor on maximum cell temperature.
159	159
160		-[[image:1733746766508-178.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="184" width="800"]]
	220	+Value of the charge current limit at given SOC, temperature, contactors temperature, maximum cell voltage and maximum cell temperature is calculated as follows:
161	161
162		-* Option 3: Limit charge current by the maximum cell voltage - a flag to enable correction of maximum allowable charging current Kcv depending on maximum cell voltage;
163		-* Option 3: Cell voltage x Factor – the dependence of the correction factor on maximum cell voltage.
	222	+**Charge current limit = Maximum charge current × Kcs × Kcc × Kcv × Kct**
164	164
165		-[[image:1733746766509-971.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="217" width="800"]]
166		-
167		-Value of the charge current limit at given SOC, temperature, contactors temperature and maximum cell voltage is calculated as follows:
168		-
169		-Charging current limit = Maximum charging current × Kcs × Kcc × Kcv
170		-
171	171	=== Discharge map ===
172	172
173	173	The BMS Mini device calculates maximum allowable discharge current values in respect to SOC, battery temperature, contactor temperature and cell voltage.
...	...	@@ -176,31 +176,70 @@
176	176
177	177	To configure parameters for determining the discharge current limit, select the "Control → Discharge map" section:
178	178
179		-[[image:1733746766511-477.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="149" width="800"]]
	232	+[[image:1740397304972-174.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="182" width="800"]]
180	180
181	181	In this section:
182	182
183	183	* Enable – a flag to start calculation of the discharge current limit;
184		-* Maximum discharge current – a maximum allowable value of the discharge current (under normal conditions):
185		-* Option 1: Limit discharging current by the battery SOC and temperature – a flag to enable correction of maximum allowable discharging current Kds depending on SOC and temperature;
	237	+* Maximum discharge current – a maximum allowable value of the discharge current (under normal conditions), A;
	238	+* Rate of change – a rate of change the current limit to a new value (0 is for immediate change), A/s;
	239	+* Option 1: Limit discharging current by the battery SOC and temperature – a flag to enable correction of maximum allowable discharging current **Kds **depending on SOC and temperature;
186	186	* Option 1: SOC x Temperature x Factor – the dependence of the correction factor on SOC and battery temperature;
	241	+* Option 2: Limit discharge current by the contactor temperature – a flag to enable correction of maximum allowable discharging current **Kdc** depending on contactor temperature;
	242	+* Option 2: Contactor temperature x Factor – the dependence of the correction factor on SOC and contactor temperature;
	243	+* Option 3: Limit discharge current by the cell voltage - a flag to enable correction of maximum allowable discharging current **Kdv** depending on minimum cell voltage;
	244	+* Option 3: Cell voltage x Factor – the dependence of the correction factor on minimum cell voltage;
	245	+* Option 4: Limit discharge current by the cell temperature - a flag to enable correction of maximum allowable discharging current **Kdt** depending on maximum cell temperature;
	246	+* Option 4: Cell voltage x Factor – the dependence of the correction factor on minimum cell temperature.
187	187
188		-[[image:1733746766512-300.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="195" width="800"]]
	248	+Value of the discharge current limit at given SOC, temperature, contactors temperature, minimum cell voltage and maximum cell temperature is calculated as follows:
189	189
190		-* Option 2: Limit discharge current by the contactor temperature – a flag to enable correction of maximum allowable discharging current Kdc depending on contactor temperature;
191		-* Option 2: Contactor temperature x Factor – the dependence of the correction factor on SOC and contactor temperature;
	250	+**Discharge current limit = Maximum discharge current × Kds × Kdc × Kdv × Kdt**
192	192
193		-[[image:1733746766513-161.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="183" width="800"]]
	252	+=== Main contactor ===
194	194
195		-* Option 3: Limit discharge current by the cell voltage - a flag to enable correction of maximum allowable discharging current Kdv depending on minimum cell voltage;
196		-* Option 3: Cell voltage x Factor – the dependence of the correction factor on minimum cell voltage.
	254	+The BMS Mini 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 a case of sealing of the charging or discharging contactors.
197	197
198		-[[image:1733746766514-686.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="215" width="800"]]
	256	+The Main contactor algorithm supports the following modes:
199	199
200		-Value of the discharge current limit at given SOC, temperature, contactors temperature and minimum cell voltage is calculated as follows:
	258	+* Always on;
	259	+* Automatic.
201	201
202		-Discharging current limit = Maximum discharging current × Kds × Kdc × Kdv
	261	+In “Always on” mode main contactor closes if all the following is true:
203	203
	263	+* Other contactors are open;
	264	+* There are no errors from the "Errors 1, 2 ..." bitfileds.
	265	+
	266	+In “Always on” mode main contactor opens if all the following is true:
	267	+
	268	+* Other contactors are open;
	269	+* There is an error from the the "Errors 1, 2 ..." bitfileds.
	270	+
	271	+In “Automatic” mode, the main contactor closes by internal algorithms at the same time with other contactors.
	272	+
	273	+In “On demand” mode, the main contactor closes by external the “Close Main contactor” request.
	274	+
	275	+(% class="box infomessage" %)
	276	+(((
	277	+**Note: **when errors occur in the system, the **Main **contactor opens either immediately or with the delay T,,off,, (depends on the settings described below).
	278	+)))
	279	+
	280	+To change the parameters of the main contactor, select the "Control → Main contactor" section:
	281	+
	282	+[[image:1740397558976-651.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="144" width="800"]]
	283	+
	284	+In this section:
	285	+
	286	+* Enable – a flag to enable the main contactor control;
	287	+* Algorithm – main contactor control algorithm:
	288	+** Always on – contactor is always closed;
	289	+** Automatic – contactor closes by internal charge and discharge algorithms;
	290	+** On demand – contactor is closed by an external request;
	291	+* Time to keep the contactor closed before closing the others – a time for other contactors to be open after the main contactor is closed;
	292	+* Delay before opening the contactor – a time which is used to detect conditions for opening the contactor, s;
	293	+* Keep the contactor open until the device is restarted – a flag for keeping the main contactor open until the system is reset;
	294	+* Errors 1, 2 to open the main contactor – bitfields to choose the errors which will open the main contactor.
	295	+
204	204	=== Charge ===
205	205
206	206	There are two contactors that serve charging the battery: a charging contactor and an allow charging contactor. With the help of the allow charging contactor, the BMS commands the charger to start or stop charging.
...	...	@@ -385,38 +385,8 @@
385	385	* Maximum voltage – maximum battery voltage, V;
386	386	* Switch off the discharging (AUX) contactor on errors – the auxiliary (AUX) discharging contactor opens if the following errors occur: Undervoltage, Overcurrent, High temperature (DCH), Short circuit, Critical error.
387	387
388		-=== Main contactor ===
	480	+=== ===
389	389
390		-The BMS Mini 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 a case of sealing of the charging or discharging contactors.
391		-
392		-The main contactor closes if there are no errors from the list below:
393		-
394		-* Overcurrent;
395		-* Undervoltage;
396		-* Overvoltage;
397		-* High temperature (CH);
398		-* High temperature (DCH);
399		-* Unallowable charging;
400		-* Critical error.
401		-
402		-The main contactor opens if the charging and discharging contactors are opened and any of the following conditions is met:
403		-
404		-* charging or discharging current is detected during a set time;
405		-* voltage of any cell is lower than the minimum cell voltage configured in the section "Protections → Undervoltage" during a set time;
406		-* voltage of any cell is greater than the maximum cell voltage configured in the section "Protections → Overvoltage" during a set time;
407		-* temperature of any cell is greater than the maximum cell temperature configured in the section "Protections → High temperature" during a set time;
408		-* Critical error stays on during a set time.
409		-
410		-To change the parameters of the main contactor, select the "Control → Main contactor" section:
411		-
412		-[[image:1733746797002-498.png||data-xwiki-image-style-alignment="center" data-xwiki-image-style-border="true" height="93" width="800"]]
413		-
414		-In this section:
415		-
416		-* Enable – a flag to enable the main contactor control;
417		-* Delay before opening the contactor – a time which is used to detect conditions for opening the contactor, second;
418		-* Keep the contactor open until the device is restarted – a flag for keeping the main contactor opened until the system be reset.
419		-
420	420	=== Cell balancing ===
421	421
422	422	Balancing makes the voltage of all cells be equal to the minimum cell voltage.

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