RU2695646C1 - Device for automatic monitoring and equalization of charging degree of parallel-series connection of accumulators of unit - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to electrical engineering and can be used in devices intended for monitoring and levelling of charge parallel-series-connected accumulators, for example, in vehicle unit. Device comprises a power supply in the form of a unit of parallel-series-connected n accumulators, system of battery consumption and charging mode under operation conditions, accumulator switching unit with pairing keys to electric parameters measurement buses, note here that control windings of switches with low internal resistance are connected by their outputs to corresponding outputs of switching control unit. Sensor switching unit comprises temperature sensor switches forming odd and even rows via serial connection. All temperature sensors measuring temperature of accumulators of odd and even rows of accumulator batteries are connected to temperature busbars of accumulators. Displays of temperature distribution of odd and even rows, which are connected in parallel to accumulator batteries, display temperature-related accumulators. Unit for measuring electrical parameters of the accumulator battery by means of a microcontroller, overcharge and undercharge compensation units as per the control signal from the microcontroller is connected to the process of balancing the accumulator battery charge degree.EFFECT: high reliability and longer service life of the unit of parallel-series-connected batteries.5 cl, 4 dwg

Description

The invention relates to the field of electrical engineering and can be used in devices designed for continuous automatic control and equalization of the degree of charge of parallel-series connected batteries in a unit mounted on a vehicle, such as a hybrid car or electric vehicle.

The prior art device for automatic control and equalization of the degree of charge of the battery pack of the combined power plant according to the patent for the invention (RU 2626378, IPC (2016.01): Н01М 10/48, published July 26, 2017), containing a power source in the form of a block of series-connected batteries, the system of the mode of consumption and charging of the battery of the unit, a group of one-position normally open keys with low internal resistance, two electric buses, while the positive poles of the batteries the windows with odd numbers are connected to one bus, and all the positive poles of the accumulators of the unit with even numbers to another bus, a microcontroller connected to the unit for generating voltage deviations from the average value, an information bus with a digital indicator of the serial numbers of the problem batteries of the unit and the switching control unit installed with the possibility of sequentially connecting the battery of the unit to two electric buses.

The disadvantages of the analogue include the lack of the ability to continuously monitor and equalize the degree of charge of each of the batteries of the unit, the lack of the ability to simultaneously control the temperature and voltage of each of the batteries when the voltage in the battery (battery) reaches several hundred volts.

The closest, in technical essence to the present invention, relates to a temperature control system for a parallel-series-connected battery pack according to the invention patent (US 9257729 B2, IPC: Н01М 10/50 (2006/01), publication of 02/09/2016). According to the invention, in the general case, the battery of the battery of an electric vehicle is a parallel-series connection of cells. Battery cells are horizontally connected in parallel, and the resulting rows are connected in series.

The vehicle includes a rechargeable battery of an electric vehicle, which is a parallel-serial connection of the cells, and the battery cells are horizontally connected in parallel, and the received rows are connected in series, the temperature control system of the battery through temperature sensors and temperature control using the controller, a control system that monitors and controls the overall functioning of various subsystems of the car. Also, this system monitors the charge level and discharge rate, both during the operation of the car and in idle mode, while the controller compares the measured voltages with each other, setting, for example, the maximum allowable difference.

The disadvantages of the prototype include:

отсутствие возможности непрерывного контроля и выравнивания степени заряженности каждого из аккумуляторов блока;

lack of the ability to continuously monitor and equalize the degree of charge of each of the batteries of the unit;

функциональная разобщенность, и следовательно, сложность схемотехнического решения проблемы одновременного контроля температуры и напряжения;

functional disunity, and therefore, the complexity of the circuit solution to the problem of simultaneous control of temperature and voltage;

отсутствие хорошей диэлектрической развязки между силовым высоковольтным блоком аккумуляторов, на котором напряжение в АКБ может достигать нескольких сотен вольт, и низковольтными частями контроля напряжения и температуры. Поэтому в прототипе рекомендуется разбивать высоковольтные аккумуляторные блока на несколько последовательно соединенных модулей из параллельно-последовательных аккумуляторов объединяя их в герметичный блок АКБ, что влечет за собой дополнительные технические сложности и снижение надежности.

the lack of good dielectric isolation between the high-voltage power battery pack, on which the voltage in the battery can reach several hundred volts, and the low-voltage parts of voltage and temperature control. Therefore, in the prototype it is recommended to break the high-voltage battery packs into several series-connected modules from parallel-series batteries by combining them into a sealed battery pack, which entails additional technical difficulties and reduced reliability.

The objective of the invention is to increase reliability and increase the life of the block of parallel-series-connected batteries, expanding the functionality, providing simultaneous balancing of both recharged and undercharged batteries with high efficiency during continuous operation in charging and power consumption mode.

The technical result is as follows:

1. The temperature of each battery and the temperature of the medium inside the sealed housing of the battery pack are simultaneously monitored.

2. One system simultaneously performs the following functions.

Control:

контроль электрических параметров (напряжение и внутреннее сопротивление каждого аккумулятора блока;

control of electrical parameters (voltage and internal resistance of each battery of the unit;

контроль температуры каждого аккумулятора;

temperature control of each battery;

контроль температуры среды внутри герметичного корпуса блока аккумуляторов в виде среднего значения при измерении в нескольких точках;

monitoring the temperature of the medium inside the sealed housing of the battery pack in the form of an average value when measured at several points;

контроль разницы между температурой среды внутри корпуса блока аккумуляторов и температурой на каждом из аккумуляторов блока;

control of the difference between the temperature of the medium inside the housing of the battery pack and the temperature on each of the battery packs;

выявление недопустимых отклонений напряжений рядов аккумуляторов при перезаряде и недозаряде;

identification of unacceptable deviations of the voltage of the rows of batteries during overcharging and undercharging;

выявление проблемного аккумулятора и индикация на дисплее его порядкового номера в ряде АКБ по распределению температуры аккумуляторов в проблемном ряде аккумуляторов;

identifying a problem battery and displaying its serial number in a number of batteries for the distribution of battery temperature in a problem row of batteries;

отображение на экране распределения температуры в виде графика в ряде параллельно соединенных аккумуляторов, содержащей проблемный аккумулятор;

display on the screen of the temperature distribution in the form of a graph in a series of parallel-connected batteries containing a problem battery;

датчики температуры не требуют диэлектрической изоляции относительно корпуса аккумулятора и, следовательно, имеют высокую точность и малую тепловую инерцию при контроле температуры.

temperature sensors do not require dielectric isolation relative to the battery case and, therefore, have high accuracy and low thermal inertia when monitoring temperature.

Alignment:

выравнивание степени заряженности осуществляется адресно и пропорционально степени разбаланса каждого из аккумуляторов, как при перезаряде, так и при недозаряде аккумуляторов блока;

equalization of the degree of charge is carried out targetedly and in proportion to the degree of imbalance of each of the batteries, both during recharging and undercharging of the battery of the unit;

выравнивание осуществляется импульсными токами величиной больше ампера при КПД более 80%.

equalization is carried out by pulse currents larger than amperes with an efficiency of more than 80%.

3. A good dielectric isolation between the high-voltage power part and the low-voltage control system is provided, while the voltage in the battery can reach several hundred volts.

4. The system is implemented on the basis of a serial element base and does not require the development of additional original elements, which significantly reduces the cost of the device.

The technical result is achieved due to the fact that the device for automatic monitoring and equalization of the degree of charge of the parallel-serial connection of the battery of the block contains a power source in the form of a block of parallel-serial connection of the batteries, a system of the mode of consumption and charging of the battery of the block, the switching unit of the batteries, two buses for measuring electrical parameters, the switching control unit and the microcontroller, while the positive poles of the series connected a the unit’s accumulators with odd numbers are connected to one bus, and all the positive poles of the unit’s evenly connected accumulators are connected to the other bus, the microcontroller is connected to the electrical parameters measuring unit, and the information bus is connected to the digital indicator of the unit’s battery problems and the control unit input switching, installed with the possibility of sequentially connecting the battery of the unit to the buses for measuring electrical parameters. The difference according to the invention is that each battery of the battery pack is equipped with a resistor of the same small size and a temperature sensor, while with one terminal a resistor of the same small value and a temperature sensor are electrically connected to the positive terminal of each battery; parallel connection of the batteries in the block for each horizontal row of batteries is performed by combining the second terminals of resistors of the same small value into the common output of a number of batteries of the block, the obtained rows are connected in series into a single battery block, which is m parallel-connected batteries, forming n rows in series connection and the total number (m × n); the battery pack is equipped with temperature sensors uniformly distributed throughout the internal volume of the sealed housing of the battery pack, each of which is electrically grounded with one terminal; the battery pack has two outputs from rows j and h for communication, respectively, with compensation blocks for overcharging and undercharging, when equalizing the degree of charge of the battery pack; equipped with a temperature sensor switching unit containing temperature sensor keys with control windings installed in the form of m parallel-connected temperature sensor keys forming odd and even rows in series connection with a total number m × (n + 1), moreover, n + 1 row is set for measuring the temperature of the medium inside the sealed enclosure of the battery pack, by the odd-numbered and even-numbered analogue control windings of the rows of keys of the temperature sensors odd-numbered and even-numbered in series connection m inputs, temperature measuring buses of the batteries connecting the outputs of the temperature sensor switching unit with odd and even inputs of the battery temperature measuring units, odd and even rows of temperature measuring units of the batteries in parallel connected m unit batteries, including: including: a pulse transformer with two primary series connected and one secondary windings, diode blocks with capacitors, instrumentation amplifier with two inputs and one output, digital ind katorom problematic temperature battery unit, displays the temperature distribution of the odd and even rows of m parallel-connected accumulators through the serial connection, the temperature distribution of the histogram displaying in rows, comprising the problem of battery temperature; compensation units for overcharging and undercharging the accumulators of the unit, wherein the accumulator switching unit is configured to commute the common terminals of the rows in series connection m parallel-connected accumulators of the unit with buses for measuring electrical parameters, the odd and even rows of keys of the temperature sensors with one terminal are connected to the corresponding odd temperature sensors and even rows of accumulators of the unit, and other leads connected to the buses for measuring the temperature of the accumulators, respectively the odd and even rows, the common output of the combined odd and even rows of keys of the temperature sensors is connected via the odd and even buses of the battery temperature measurement to the first inputs of the odd and even temperature measurement blocks, and the second input of the temperature measurement block of the odd rows of temperature sensors is connected to the even bus of electrical measurements parameters, the second input of the temperature measuring unit of even rows of temperature sensors is connected to the odd bus of measuring electrical parameters, the outputs of the blocks are measured The temperatures of the odd and even rows of temperature sensors are connected to the inputs of the instrumentation amplifier and the microcontroller, some outputs of the control windings of the keys of the temperature sensors are installed with the possibility of pairwise connection to the neighboring outputs of the switching control unit, and the second conclusions are connected to the corresponding m inputs of the analog switches, to the inputs of the analog switch the odd and even rows are connected to the control windings of the keys, respectively, the odd and even rows of temperature sensors, and the outputs are analog of the output switches are grounded, the switching control unit, odd and even analogue switches, digital indicators of the battery of the unit that are problematic in temperature and electric parameters, displays the temperature distribution of the odd and even rows of m batteries connected in parallel through the serial connection, are connected to the microcontroller by information buses and are controlled by it input unit

of electrical parameters of parallel connected n rows of m batteries is connected to the buses for measuring electrical parameters, and with the output from the microcontroller, inputs, the battery recharge compensation unit is connected to the buses for measuring electrical parameters and the control signal to the microcontroller, and the output is connected to the jth row of the battery block, the inputs, the battery under-charge compensation unit is connected to the buses for measuring electrical parameters and the control signal to the microcontroller, and the output is connected to the h-th row of blocks batteries, and the voltage of the hth row is greater than the voltage of the jth row.

Also, the differences are that each of the temperature sensors is installed inside the housing of the corresponding battery, the temperature sensors are made in the form of thermistors with large internal resistance, resistors of the same small size in the battery pack, with unacceptable voltage deviations in problem batteries, are fuses, the number of sensors temperature uniformly placed on the internal volume of the sealed housing of the battery pack is equal to the number of batteries in a row.

The essence of the proposed invention is illustrated by drawings, which depict:

FIG. 1 is a block diagram of a device of the invention;

FIG. 2 - oscillograms of control of electrical parameters and temperature;

FIG. 3 - waveform alignment of electrical parameters when recharging;

FIG. 4 - an oscillogram of the alignment of electrical parameters during undercharging.

The device of the proposed invention contains:

источник питания в виде размещенного в герметичном корпусе блока m параллельно соединенных аккумуляторов 1 (АКБ), образующих n рядов по последовательному соединению и общим количеством (m×n), причем, к положительному контакту каждого аккумулятора электрически присоединены одними выводами резистор одинаково малой величины и датчик температуры (например, терморезистор с большим внутренним сопротивлением);

a power source in the form of m parallel-mounted accumulators 1 (battery) located in a sealed enclosure of a block m, forming n rows in series connection and a total number (m × n), moreover, an equally small resistor and a sensor are electrically connected to the positive terminal of each battery temperature (for example, a thermistor with a large internal resistance);

в блоке аккумуляторов равномерно размещены по внутреннему объему герметичного корпуса датчики температуры для измерения температуры его среды;

temperature sensors for measuring the temperature of its environment are uniformly placed in the battery pack along the internal volume of the sealed enclosure;

блок АКБ имеет два вывода от рядов h и j для связи соответственно с блоками компенсации перезаряда 21 (БКп) и недозаряда 22(БКн) при выравнивании степени заряженности аккумуляторов АКБ;

the battery pack has two outputs from the rows h and j for communication with the compensation blocks for overcharge 21 (BKp) and undercharge 22 (BKn), respectively, when equalizing the degree of charge of the battery;

систему режима потребления и зарядки 2 (СПЗ) АКБ в условиях эксплуатации;

system of consumption and charging mode 2 (SDR) of the battery in operating conditions;

блок коммутации аккумуляторов 3 (БКА) содержит n+1 однопозиционных нормально-разомкнутых ключей с малым внутренним сопротивлением (дальше по тексту, ключей с малым внутренним сопротивлением) и управляющими обмотками, попарно подключающим к шинам измерения электрических параметров 4 (а), 5 (б) n последовательно включенных рядов аккумуляторов, причем, управляющие обмотки ключей с малым внутренним сопротивлением связаны одними выводами с соответствующими выходами блока управления коммутацией 7 (БУК), а другими заземлены;

accumulator switching unit 3 (BKA) contains n + 1 one-position normally open keys with low internal resistance (hereinafter referred to as keys with low internal resistance) and control windings connecting in pairs to the buses for measuring electrical parameters 4 (a), 5 (b ) n series-connected rows of batteries, moreover, the control windings of the keys with low internal resistance are connected by one terminal to the corresponding outputs of the switching control unit 7 (BUC), and the others are grounded;

блок коммутации аккумуляторов 3 (БКА) содержит n+1 ключей с малым внутренним сопротивлением и управляющими обмотками;

battery switching unit 3 (BKA) contains n + 1 keys with low internal resistance and control windings;

в каждом ряду аккумуляторов АКБ вторые выводы резисторов малой величины объединены в общий провод ряда аккумуляторов;

in each row of battery batteries, the second terminals of small resistors are combined into a common wire of a number of batteries;

шина измерения электрических параметров 4 (а), к которой присоединены все общие провода последовательно соединенных рядов аккумуляторов АКБ с нечетными номерами;

bus for measuring electrical parameters 4 (a), to which all common wires of series-connected rows of battery batteries with odd numbers are connected;

шина измерения электрических параметров 5 (б), к которой присоединены все общие провода последовательно соединенных рядов аккумуляторов АКБ с четными номерами;

bus for measuring electrical parameters 5 (b), to which all common wires of series-connected rows of battery batteries with even numbers are connected;

блок коммутации датчиков температуры 6 (БКДт), содержит однопозиционные нормально-разомкнутые ключи датчиков температуры (дальше по тексту, ключи датчиков температуры) с управляющими обмотками, установленные в виде m параллельно соединенных ключей датчиков температуры, образующих нечетные и четные ряды по последовательному соединению общим количеством (n+1), причем, n+1 ряд установлен для измерения температуры среды, внутри герметичного корпуса аккумулятора;

Temperature Sensor Switching Unit 6 (BKDt), contains one-position normally open temperature sensor keys (hereinafter referred to as temperature sensor keys) with control windings installed in the form of m parallel connected temperature sensor keys forming odd and even rows in a series connection (n + 1), moreover, n + 1 row is installed to measure the temperature of the medium inside the sealed battery case;

все датчики температуры, измеряющие температуру аккумуляторов нечетных и четных рядов АКБ, через нечетные и четные ряды ключей датчиков температуры подсоединены к шинам измерения температуры аккумуляторов 10 (в), и 11 (г);

all temperature sensors that measure the temperature of the batteries of odd and even rows of batteries through the odd and even rows of keys of the temperature sensors are connected to the temperature measurement buses of the batteries 10 (c), and 11 (g);

в каждом ряду ключей датчиков температуры, одни выводы объединены в общий провод, и все нечетные ряды подсоединены к шине измерения температуры аккумуляторов 10 (в), вторыми выводами ключи датчиков температуры присоединены ко вторым выводам датчиков температуры установленных на аккумуляторах каждого нечетного ряда;

in each row of temperature sensor keys, one terminal is combined into a common wire, and all the odd rows are connected to the battery temperature measurement bus 10 (c), the second terminal of the temperature sensor keys are connected to the second terminal of the temperature sensors installed on the batteries of each odd row;

в каждом ряду ключей датчиков температуры, одни выводы объединены в общий провод, и все четные ряды подсоединены к шине измерения температуры аккумуляторов 11 (г), вторыми выводами ключи датчиков температуры присоединены ко вторым выводам датчиков температуры установленных на аккумуляторах каждого четного ряда;

in each row of temperature sensor keys, one terminal is combined into a common wire, and all even rows are connected to the battery temperature measuring bus 11 (g), the second terminal of temperature sensor keys are connected to the second terminal of temperature sensors installed on the batteries of each even row;

вторые выводы управляющих обмоток нечетных и четных ключей датчиков температуры соответственно связаны с входами нечетного и четного аналоговых коммутаторов 8 (АКн) и 9 (АКч);

the second conclusions of the control windings of the odd and even keys of the temperature sensors are respectively connected to the inputs of the odd and even analog switches 8 (AKN) and 9 (AKh);

блок управления коммутации 7 (БУК) представляет собой сдвоенный демультиплексор на n выходов в каждом, соединенных между собой соответствующим образом, с общим числом выходов n+1;

switching control unit 7 (BUK) is a dual demultiplexer with n outputs in each, connected to each other in a corresponding way, with a total number of outputs n + 1;

аналоговый коммутатор 8 (Кн) управляющих обмоток рядов ключей датчиков температуры нечетных по последовательному соединению, с т входами;

analog switch 8 (KN) of the control windings of the rows of keys of the temperature sensors odd in a serial connection, with t inputs;

аналоговый коммутатор 9 (Кч) управляющих обмоток рядов ключей датчиков температуры четных по последовательному соединению, с т входами;

analog switch 9 (CK) of control windings of rows of keys of temperature sensors even in serial connection, with t inputs;

шина измерения температуры аккумуляторов 10 (в) соединенная с общим выводом объединенных рядов ключей датчиков температуры, блока коммутации датчиков температуры только нечетных по последовательному соединению рядов аккумуляторов АКБ;

battery temperature measurement bus 10 (c) connected to a common terminal of the connected rows of temperature sensor keys, a temperature sensor switching unit only odd in series connection of battery battery rows;

шина измерения температуры аккумуляторов 11 (г) соединенная с общим выводом объединенных рядов ключей датчиков температуры, блока коммутации датчиков температуры только четных по последовательному соединению рядов аккумуляторов АКБ;

a battery temperature measuring bus 11 (g) connected to a common terminal of the connected rows of temperature sensor keys, a temperature sensor switching unit only of even rows of battery batteries in a serial connection;

микроконтроллер 12;

microcontroller 12;

блок измерения температуры 13 (БИТ_н) каждого ряда параллельно соединенных m аккумуляторов АКБ нечетных по последовательному соединению, включающий: импульсный трансформатор с двумя первичными последовательно соединенными и одной вторичной обмотками, диодный блок с конденсаторами;

temperature measuring unit 13 (BIT _n ) of each row of m parallel-connected battery batteries odd in series connection, including: a pulse transformer with two primary series-connected and one secondary windings, a diode block with capacitors;

блок измерения температуры 14 (БИТ_ч) каждого ряда параллельно соединенных m аккумуляторов АКБ четных по последовательному соединению, включающий: импульсный трансформатор с двумя первичными последовательно соединенными и одной вторичной обмотками, диодный блок с конденсаторами;

temperature measuring unit 14 (BIT _h ) of each row of m parallel-connected battery batteries even in series connection, including: a pulse transformer with two primary series-connected and one secondary windings, a diode block with capacitors;

инструментальный усилитель 15 (ИУ) с двумя входами и одним выходом;

instrumental amplifier 15 (DUT) with two inputs and one output;

цифровой индикатор 16 (ЦИ_Т) проблемного по температуре аккумулятора АКБ;

digital indicator 16 (TsI _T ) of a battery with a problem in temperature;

дисплей 17 (Дтн) распределения температуры нечетного ряда параллельно соединенных m аккумуляторов АКБ, отображающий гистограммы распределения температуры в рядах, содержащих проблемные по температуре аккумуляторы;

a display 17 (Dtn) of the temperature distribution of an odd row of m batteries in parallel connected batteries showing histograms of the temperature distribution in rows containing temperature-sensitive batteries;

дисплей 18 (Дтч) распределения температуры четного ряда параллельно соединенных m аккумуляторов, отображающий гистограммы распределения температуры в рядах, содержащих проблемные по температуре аккумуляторы;

a display 18 (Dtch) of the temperature distribution of an even row of m batteries connected in parallel, showing histograms of the temperature distribution in rows containing temperature-problematic batteries;

блок измерения 19 (БИэ) электрических параметров ряда параллельно соединенных m аккумуляторов АКБ, включающий: импульсный трансформатор с двумя первичными последовательно соединенными и одной вторичной обмотками, диодный блок с конденсаторами;

a measurement unit 19 (BIE) of electrical parameters of a series of parallel-connected m battery batteries, including: a pulse transformer with two primary series-connected and one secondary windings, a diode block with capacitors;

цифровой индикатор электрических параметров 20 (ЦИ_э) номера проблемного по электрическим параметрам ряда из m параллельно соединенных аккумуляторов АКБ;

digital indicator of electrical parameters 20 (CI _e ) of the number of a series of m parallel-connected battery batteries in electrical parameters;

блоки компенсации перезаряда 21 (БКп) и недозаряда 22 (БКн) аккумуляторов АКБ, каждый из которых включает согласующую цепочку, состоящую из конденсатора и резистора, силовой трансформатор с одной первичной и двумя вторичными обмотками, два однопозиционных нормально-разомкнутых ключа коммутации нечетных и четных рядов параллельно соединенных m аккумуляторов АКБ, два логических элемента схемы совпадений, триггер четности, ограничительный резистор.

compensation blocks for overcharge 21 (BKp) and undercharge 22 (BKn) of accumulator batteries, each of which includes a matching chain consisting of a capacitor and a resistor, a power transformer with one primary and two secondary windings, two single-position normally open switching keys of odd and even rows m batteries connected in parallel with the battery, two logical elements of the coincidence circuit, a parity trigger, a limiting resistor.

The proposed device operates as follows.

CONTROL.

The sequence of work on monitoring the temperature of battery batteries.

The signal of the microcontroller 12 (MK), applied to the input of the address switching of the dual demultiplexer of the switching control unit 7 (BUK) with the number of outputs n + 1, connects the first odd row of m accumulator batteries through the first and second keys with low internal resistance of switching unit 3 ( BKA) to the tires for measuring electrical parameters 4 (a) and 5 (b).

At the same time, the temperature sensors of the odd and even rows of batteries are connected through the keys of the temperature sensors to the temperature measurement buses of the batteries 10 (c) and 11 (g).

During the closed state of the first and second keys with low internal resistance of switching unit 3 (BKA), the odd and even analog switches 8 (Kn) and 9 (Kch) must have time to interrogate all temperature sensors of the odd and even rows of battery batteries, respectively. Moreover, when switching the keys of the temperature sensors, the direction of the current through the temperature sensors will be positive for odd rows, and negative for even rows.

A positive voltage is applied to the temperature sensors of the odd rows of m batteries from the buses for measuring electrical parameters 4 (a) and 5 (b), and a negative voltage to the temperature sensors of the even rows of m batteries.

Positive voltage is supplied from the temperature sensors of the odd rows from m batteries from each row battery, and the negative voltage is supplied to the temperature sensors of even rows from m batteries.

The supply voltage to the control windings of the temperature sensor keys of the temperature sensor switching unit 6 (BKDt) is supplied only from the first and second outputs of the switching control unit 7 (BUK), while the voltage from the control windings of the temperature sensor keys of the first odd and even rows of the temperature sensor switching unit 6 (BKDt) is supplied respectively to the inputs of the odd and even analog switches 8 (AKN) and 9 (AKh).

Further, with a frequency exceeding the polling frequency of the switching unit 7 (BPC) by a factor of m from the odd and even analogue switches 8 (AKN) and 9 (AKh) through the keys of the temperature sensors, a simultaneous interrogation of temperature sensors measuring the temperature of two adjacent odd and even rows of battery batteries.

Through the temperature measuring buses of accumulators 10 (c) and 11 (d), the voltage from the temperature sensors of the odd and even rows of batteries of the battery is supplied, respectively, to the inputs of the odd and even blocks of temperature measurement 13 (BIT _n ) and 14 (BIT _h ), and their outputs form a voltage proportional to the temperature for each of the batteries of the odd and even rows of battery batteries (see Fig. 2).

The voltage from each of the odd and even temperature measuring units 13 (BIT _n ) and 14 (BIT _h ) is transmitted to the microcontroller 12 (MK) and to the inputs of the instrumental amplifier 15 (DUT) for processing.

At the output of the instrumental amplifier 15 (DUT), a voltage is generated proportional to the temperature difference of the odd and even rows of battery batteries and transmitted to the microcontroller 12 (MK).

The above-described sequence of measuring the temperature of the batteries is repeated when each next row of m parallel-connected batteries is connected to the buses for measuring electrical parameters 4 (a) and 5 (6).

A survey of all battery temperature sensor accumulator, the digital display 16 (CI _t) indicated by the ordinal number of the problem on the battery temperature of rechargeable batteries, and the displays 17 (L _t) and 18 (D _PM) displays the temperature distribution as a histogram, respectively odd and even a parallel connected row of m battery batteries containing a temperature-problematic battery.

The sequence of work on monitoring the electrical parameters of battery batteries.

When sequential pairwise interrogation of keys with a low internal resistance of unit 3 (BKA) from the switching control unit 7 (BUK) on the measurement buses of electrical parameters 4 (a) and 5 (6), positive and negative rectangular voltages alternate with an amplitude proportional to the voltage on each of the batteries of the battery (see Fig. 2), which simultaneously enters the inputs of the block 19 (BIe) for measuring electrical parameters, block 21 (BC _p ) compensation for overcharging the batteries of the battery and block 22 (BC _n ) compensation for undercharging battery pack accumulators.

In block 19 (BIE) for measuring electrical parameters, an average voltage value is generated for all rows of battery batteries and, when the amplitude of the mismatch voltage on any of the rows of battery batteries is different from the average value, the output of block 19 (BIE) for measuring electrical parameters, a voltage pulse appears, the amplitude which is proportional to the magnitude of the voltage mismatch series, and the duration is inversely proportional to the clock frequency of the survey, moreover, the positive value of the pulse voltage mismatch there is a recharge, and a negative value - undercharging of a controlled series of battery batteries

When processing the signal in the microcontroller 12 (MK), the sign (plus and minus) of the input impulse of the mismatch voltage is taken into account, since the positive impulses of the unbalance voltage correspond to overcharging, and the negative ones to undercharging of the battery batteries.

As a result, from the microcontroller 12 (MK) with a positive input impulse of the mismatch voltage, the control signals are fed to the input of the overcharge compensation block 21 (BC _p ), and with a negative input pulse of the mismatch, the control signals are fed to the input of the mismatch voltage block 22 (BC _n ) .

If the voltage deviations from the average value on the problematic battery batteries exceed the permissible limit values, the microcontroller 12 (MK) displays on the digital indicator of electrical parameters 20 (QI _e ) the serial number of the battery series of the battery problems and the nature of the malfunction (overcharging and undercharging).

LEVELING.

The alignment process begins with the receipt from the microcontroller 12 (MK) of the control voltage pulses with a duration proportional to the amplitude of the mismatch on the compensation blocks overcharge and undercharge.

Compensation blocks for overcharge 21 (BKp) and undercharge 22 (BKn) of the battery of the block, each of which includes a matching circuit consisting of a capacitor and a resistor, a power transformer with one primary and two secondary windings, two single-position normally open switches with a small internal switching resistance of odd and even rows of m batteries connected in parallel, two logic elements, coincidence circuits, parity trigger, limit resistor.

In the case of a positive impulse from the unit for measuring electrical quantities 19 (BIe) to the microcontroller 12 (MK), the compensation block for overcharge 21 (BKp) receives a pulse of a compensating voltage with a duration proportional to the value of the overcharge, and in the case of a negative impulse from the unit for measuring electric quantities 19 (BIe) to the microcontroller 12 (MK), to the undercharge charge compensation unit 22 (BKN), an impulse of the compensating voltage is received, the duration of which is proportional to the value of the undercharge.

In block compensation overcharge 21 (MKB) generated pulse compensating voltage duration proportional to the overcharge and over galvanic separation on pulse transformer block overcharge compensation 21 (BK _n) supplied to the terminal j-th row of batteries battery, wherein the pulse amplitude of the offset voltage generated on the problematic a number of battery batteries (see. Fig. 1, 3) more than the constant voltage on the j-th row of battery batteries.

In the undercharge charge compensation unit 22 (BKN), a compensating voltage pulse is generated with a duration proportional to the undercharge value and is fed through the galvanic isolation on the pulse transformer of the undercharge charge compensation unit 22 (BKN) to the output of the h-th row of battery batteries, and the amplitude of the compensation voltage pulse generated on the problem series battery batteries (see. Fig. 1, 4) is less than us h-th row of battery batteries, while the voltage of the h-th row is greater than the voltage of the j-th row.

Thus, all the measuring information on monitoring the temperature and electrical parameters of the batteries of the battery is supplied to the microcontroller 12 (MK), in which the results are processed and programmed into control signals, and visual indication on the listed external devices, while the microcontroller:

осуществляет синхронный опрос блока управления коммутацией 7 (БУК) и нечетные 8 (АКн) и четные 9 (АКч) аналоговые коммутаторы;

carries out synchronous interrogation of the switching control unit 7 (BUK) and odd 8 (AKN) and even 9 (AKh) analog switches;

осуществляет статистическую обработку сигналов по температуре нечетных и четных рядов аккумуляторов АКБ и определяет математическое ожидание и поле рассеяния температуры в контролируемых рядах аккумуляторов АКБ;

carries out statistical processing of signals by the temperature of odd and even rows of battery batteries and determines the mathematical expectation and temperature dispersion field in the controlled rows of battery batteries;

оценивает допустимую разницу в температуре нечетных и четных рядов аккумуляторов АКБ на соответствие допустимым границам;

assesses the allowable difference in temperature of the odd and even rows of battery batteries for compliance with the permissible limits;

выдает управляющую информацию на индикацию распределения температуры в проблемных нечетных и четных рядах аккумуляторов АКБ соответственно на дисплеи распределения температуры нечетного ряда 17 (Дтн) или четного ряда 18 (Дтч) и индицирует на цифровой индикатор 16 (ЦИ_т) порядковый номер проблемного по температуре аккумулятора АКБ;

gives control information to indicate the temperature distribution in problematic odd and even rows of battery batteries, respectively, on the temperature distribution displays of odd series 17 (Dtn) or even row 18 (Dtch) and displays the serial number of the battery temperature problem in temperature on digital indicator 16 (DI _t ) ;

отдельно применительно к n+1 ряду, установленному для измерения температуры среды внутри герметичного корпуса аккумулятора, вычисляет и анализирует среднюю температуру внутри герметичного корпуса аккумуляторов АКБ, сравнивает со средней температурой нечетных и четных рядов аккумуляторов АКБ по заданным границам допустимых расхождений средних температур среды и аккумуляторов для поддержания комфортных условий эксплуатации аккумуляторов АКБ;

separately with respect to the n + 1 row, set to measure the temperature of the medium inside the sealed battery case, it calculates and analyzes the average temperature inside the sealed battery case of the batteries, compares it with the average temperature of the odd and even rows of battery batteries according to the specified boundaries of the permissible differences in the average temperature of the medium and the batteries for maintaining comfortable operating conditions for batteries;

преобразует программно поступающие из блока 19 (БИэ) измерения электрических параметров, амплитуды импульсов напряжения рассогласования, в управляющие сигналы, длительностью пропорциональной амплитуде входных импульсов напряжения рассогласования и постоянной амплитуды;

converts the measurements of the electrical parameters, the amplitude of the mismatched voltage pulses, programmatically coming from the block 19 (BIe), into control signals of a duration proportional to the amplitude of the input pulses of the mismatch voltage and constant amplitude;

управляющий сигнал, от микроконтроллера с учетом знака импульса напряжения рассогласования (плюс, минус), поступает либо на вход блока 21 (БК_п) компенсации перезаряда при положительном знаке импульса, либо на вход блока 22 (БК_н) компенсации недозаряда при отрицательном знаке импульса;

the control signal from the microcontroller, taking into account the sign of the impulse of the mismatch voltage (plus, minus), is either input to the overcharge compensation unit 21 (BC _p ) with a positive pulse sign, or to the input of the undercharge charge block 22 (BC _n ) with a negative pulse sign;

индицирует на цифровой индикатор электрических параметров 20 (ЦИ_э) порядковый номер проблемного по электрическим параметрам ряда аккумуляторов АКБ и характер неисправности (перезаряд и недозаряд), при этом одновременно на соответствующие дисплеи распределения температуры нечетного ряда 17 (Дтн) или четного ряда 18 (Дтч) отображается распределение температуры по всем аккумуляторам проблемного ряда и индицирует на цифровой индикатор 16 (ЦИ_т) порядковый номер проблемного по температуре аккумулятора АКБ;

Indicate on the digital indicator of electrical parameters 20 (Tsi _e ) the serial number of the battery series of the battery problems and the nature of the malfunction (overcharge and undercharging), while simultaneously on the corresponding temperature distribution displays of the odd row 17 (Dtn) or the even row 18 (Dtch) displayed on all the batteries of the problem of a number of temperature distribution and indicates on digital display 16 (CI _t) the number of the problem on the battery temperature of the battery;

Thus, an increase in reliability and an increase in the life of the battery of the unit is achieved through continuous automatic monitoring and address voltage equalization of each of the batteries with high accuracy when equalizing currents in a pulse reaching several amperes, high energy conversion efficiency with the possibility of indicating serial numbers with an unacceptable deviation of the overcharge voltage and undercharging the battery of the unit at the minimum cost of equipment and cost per share rking battery block batteries, especially this effect increases proportionally with increasing number of accumulators in the box.

The ability to control and align the electrical parameters of the batteries in one device and at the same time control the temperature of each of them and the temperature of the sealed housing of the battery pack should be considered as a new additional diagnostic feature that increases the reliability of the system.

Claims (5)

1. The device for automatic monitoring and equalization of the degree of charge of the parallel-serial connection of the battery of the unit, containing a power source in the form of a block of parallel-serial connection of the batteries, the system of the mode of consumption and charging of the battery of the unit, the switching unit of the batteries, two buses for measuring electrical parameters, the switching control unit and a microcontroller, while the positive poles from the series-connected accumulators of the unit with odd numbers are connected are connected to one bus, and all the positive poles of the series-connected accumulators of the unit with even numbers to another bus, the microcontroller is connected to the electrical parameters measuring unit, and the information bus is connected to the digital indicator of the accumulators, which are problematic in electrical parameters, and the input of the switching control unit installed with the possibility of serial connection of the battery pack to the tires for measuring electrical parameters, characterized in that each battery of the battery pack nabzhen equally small value resistor and a temperature sensor, with one terminal of the resistor equally small magnitude and a temperature sensor electrically connected to the positive terminal of each battery; parallel connection of the batteries in the block for each horizontal row of batteries is performed by combining the second terminals of resistors of the same small value into the common output of a number of batteries of the block, the obtained rows are connected in series into a single battery block, which is m parallel-connected batteries, forming n rows in series connection and the total number (m × n); the battery pack is equipped with temperature sensors uniformly distributed throughout the internal volume of the sealed housing of the battery pack, each of which is electrically grounded with one terminal; the battery pack has two outputs from rows j and h for communication, respectively, with compensation blocks for overcharging and undercharging, when equalizing the degree of charge of the battery pack; equipped with a temperature sensor switching unit containing temperature sensor keys with control windings installed in the form of m parallel-connected temperature sensor keys forming odd and even rows in series connection with a total number m × (n + 1), and n + 1 row is set for measurement the temperature of the medium inside the sealed housing of the battery pack, by the analogue switches of the odd and even control windings of the rows of keys of the temperature sensors are odd and even through a serial connection with m inputs, buses for measuring the temperature of the batteries, connecting the outputs of the switching unit of the temperature sensors with the inputs of the odd and even blocks of measuring the temperature of the batteries, blocks for measuring the temperature of the batteries of odd and even rows of parallel-connected m batteries of the unit in series connection, including: a pulse transformer with two primary series connected and one secondary windings, diode blocks with capacitors, instrumental amplifier with two inputs and one in output, a digital indicator of the temperature-problematic battery unit, displays of the temperature distribution of the odd and even rows of m batteries connected in series connected in series, showing histograms of the temperature distribution in rows containing temperature-problematic batteries; compensation units for overcharging and undercharging the accumulators of the unit, while the accumulator switching unit is configured to switch the common terminals of the rows in series connection m parallel-connected accumulators of the unit with buses for measuring electrical parameters, the odd and even rows of temperature sensor keys are connected by one terminal to the corresponding odd temperature sensors and even rows of accumulators of the unit, and other leads connected to the buses for measuring the temperature of the batteries, respectively the odd and even rows, the common output of the combined odd and even rows of keys of the temperature sensors is connected via the odd and even buses of the battery temperature measurement to the first inputs of the odd and even temperature measurement blocks, and the second input of the temperature measurement block of the odd rows of temperature sensors is connected to the even bus of electrical measurements parameters, the second input of the temperature measuring unit of even rows of temperature sensors is connected to the odd bus of measuring electrical parameters, the outputs of the blocks are measured I the temperatures of the odd and even rows of temperature sensors are connected to the inputs of the instrumentation amplifier and the microcontroller, some of the outputs of the control windings of the keys of the temperature sensors are installed with the possibility of pairwise connection to the neighboring outputs of the switching control unit, and the second conclusions are connected to the corresponding m inputs of the analog switches, to the inputs of the analog switch the odd and even rows are connected to the control windings of the keys, respectively, the odd and even rows of temperature sensors, and the outputs of the analog of the output switches are grounded, the switching control unit, odd and even analogue switches, digital indicators of the battery of the unit that are problematic in temperature and electric parameters, displays the temperature distribution of the odd and even rows of m batteries connected in parallel through the serial connection, are connected to the microcontroller by information buses and are controlled by it , the unit for measuring electrical parameters of parallel connected n rows of m batteries is connected to the measurement buses by electrical inputs parameters, and the output with the microcontroller, the inputs, the battery recharge compensation unit is connected to the electric parameter measurement buses and the control signal to the microcontroller, and the output is connected with the jth row of the battery unit, the inputs, the battery undercharger compensation unit is connected to the electric measurement bus and the control a signal with a microcontroller, and the output is connected to the hth row of the battery pack, and the voltage of the hth row is greater than the voltage of the jth row. 2. The device according to p. 1, characterized in that each of the temperature sensors measuring the temperature of the battery is installed inside the housing of the corresponding battery. 3. The device according to p. 1, characterized in that the temperature sensors are made in the form of thermistors with high internal resistance. 4. The device according to claim 1, characterized in that the small resistors in the battery pack, with unacceptable voltage deviations in the problem batteries, are fuses. 5. The device according to claim 1, characterized in that the number of temperature sensors evenly spaced across the internal volume of the sealed housing of the battery pack is equal to the number of batteries in the row.

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