RU153793U1 - BATTERY MANAGEMENT SYSTEM - Google Patents

Abstract

1. A battery consisting of many cells, characterized in that the cells of the battery are connected in series by direct current, and by alternating current in parallel through a transformer balancing system. 2. The battery according to claim 1, characterized in that each cell is equipped with a DC-to-AC converter. 3. The battery according to claim 1, characterized in that the converters are synchronized by a common control signal from the common control unit.

Description

The utility model relates to electrical engineering and can be used in chargers of lithium-ion batteries.

With the advent of lithium batteries, the problem of their proper use has become acute. For example, in electric vehicles at high capacities and currents, such batteries turned out to be very sensitive to overcharging and overdischarging, which makes them fail. Batteries are also sensitive to improper operation (memory effect, polarity reversal, sulfation, etc.), but with small capacities and relative cheapness this problem is not so urgent. The Battery Management System (SUAKB) solves the problem of maintaining the battery in optimal condition for a long time without the need for frequent intervention by specialists for periodic maintenance and diagnostics. It also solves a number of secondary tasks related both to maintenance and diagnostics (in case of serious problems), and (in the future) with the introduction of additional functionality, such as tracking the position of a vehicle.

In the process of functioning of rechargeable batteries (batteries) based on lithium-ion technology, the task arises of maintaining the cells of the batteries in a balanced state, because the cells immediately after production have slightly different characteristics, and this difference may be aggravated over time. If you do not constantly monitor the state of the cells, the battery may fail quickly enough.

When charging the battery, recharge of the battery cells should be prevented, which leads to the fact that one recharged cell forces the charger to stop the process, and other battery cells may not be fully charged.

Traditionally, this problem is solved using special devices called BTS - Battery Maagement System, which implement the following functions:

- prevention of overdischarge of cells (as soon as the voltage on any cell falls below a certain threshold, the BMS forcibly disconnects the load until the battery is recharged);

- prevention of overcharging cells (as soon as the voltage on any cell becomes higher than a certain threshold, BMS disables the memory);

- cell balancing (when the voltage on any cell becomes higher than a certain threshold, which is below the threshold for switching off the memory, BMS starts to expend excess charge from the cell through a special energy-consuming element).

When balancing cells, they usually equalize either voltage or charge on the cells. There are two ways to implement balancing:

- passive

- active.

With a passive circuit, the excess charge of some cells is spent idle through resistors so that the remaining cells can continue to charge. Such a system is simple, but it generates a lot of heat, it takes a lot of time and only works when charged. When discharged, the passive system can only turn off the entire battery when the weakest cell is discharged. Thus, the capacity of the entire battery (in ampere-hours) will be equal to the capacity of the weakest cell.

The prior art microcircuit BQ77PL900, which provides protection for battery packs with 5-10 series-connected batteries. The microcircuit is a functionally complete unit and can be used to work with the battery compartment. Comparing the cell voltage with the threshold, the chip, if necessary, turns on the balancing mode for each of the cells. If the voltage of any battery exceeds a predetermined threshold, field-effect transistors are turned on and a load resistor is connected in parallel with the battery cell, through which current goes around the cell and no longer charges it. The remaining cells while continuing to charge. When the voltage drops, the field effect transistor closes and charging can continue. Thus, at the end of charging, all cells will have the same voltage.

When applying the balancing algorithm, which uses only the voltage deviation as a criterion, incomplete balancing is possible due to the difference in the internal resistance of the batteries, on which part of the voltage drops when current flows through the battery, which, in turn, introduces an additional error in the voltage spread during charging . The battery protection microchip cannot determine what caused the imbalance - by the different capacity of the batteries or by the difference in their internal resistances. Therefore, with this type of passive balancing, there is no guarantee that all batteries will be 100% charged.

The BQ22084 chip uses an improved version of the balancing, also based on a change in voltage, but in order to minimize the effect of the spread of internal resistances, the BQ2084 balances closer to the end of the charging process when the charge current is small.

In this technology, for each battery, the Qneed charge required to fully charge it is calculated, after which the difference between the Qneed of all batteries is found. Then, the microcircuit includes power switches, which discharge all cells to the level of the least charged, until the charges equalize.

Due to the fact that the difference in the internal resistances of the batteries does not affect this method, it can be used at any time, both when charging and when discharging the battery. The main advantage of this technology is more accurate battery balancing compared to other passive methods.

Active control systems are divided into capacitive (on capacitors) and inductive (on chokes), all of them are characterized by redistribution of charge between cells, which occurs only between adjacent cells or groups of cells. Capacitance and inductance can build up and give off charge. It is on this principle that balancing is built. The storage cell (C or L) connects to the battery and stores energy from it, then it connects to the neighboring battery and gives up the stored energy if the connected battery has a lower voltage than the storage cell. Balancing occurs over many cycles of energy transfer between batteries and storage cells. Energy is transferred between two adjacent cells in the battery. In terms of energy efficiency, this method is superior to passive balancing, as It transfers energy from a more charged cell to a less charged one with minimal energy loss. This method is preferable in cases when it is required to provide the maximum operating time without recharging.

The prior art for active battery balancing is known to TI's BQ78PL14 chip, manufactured using PowerPump technology, which uses an inductive converter to transmit energy. PowerPump uses an n-channel p-channel field effect transistors and an inductor, which is located between a pair of batteries. Field effect transistors and a choke constitute a step-down / step-up converter. Energy losses are small and almost all of the energy flows from a heavily charged battery to a low charged one. Due to the high balancing currents, PowerPump technology is much more efficient than conventional passive balancing with energy dissipation. In the case of balancing the laptop battery pack, the balancing currents are 25 ... 50 mA. By choosing the value of the components, it is possible to achieve balancing efficiency 12-20 times better than with the passive method with internal keys. A typical unbalance value (less than 5%) can be achieved in one or two cycles.

The prior art microcircuit ICL7660 (MAX1044 or domestic counterpart KR1168EP1) charge transfer, which uses not an inductive but a capacitive storage (voltage converters on switched capacitors). Basically, the microcircuit is used to obtain a negative voltage equal to its supply voltage. However, if the negative voltage at its output turns out to be larger for some reason than the positive supply voltage, then the microcircuit will begin to pump the charge “in the opposite direction”, taking it from the minus, and giving it to the plus, i.e. she is constantly trying to balance these two tensions. This property was used to balance two battery cells. The microcircuit with a high frequency connects the capacitor to either the upper or lower battery. Accordingly, the capacitor will be charged from a more charged one and discharged to a more discharged one, each time transferring some portion of the charge. Over time, the voltage on the batteries will become the same. The energy in the circuit practically does not dissipate, the efficiency of the circuit can reach 95 ... 98% depending on the voltage on the batteries and the output current, which depends on the switching frequency and capacitor. At the same time, the consumption of the microcircuit is only a few tens of microamps, i.e. is below the self-discharge level of many batteries, and therefore the chip can not be disconnected from the battery, and it will do the work of equalizing the voltage on the cells. The pumping current can reach 30 ... 40 mA, but the efficiency is reduced. The supply voltage can be from 1.5 to 10 V, which means that the microcircuit can balance both normal Ni-Mh fingers and lithium batteries.

This utility model is designed to protect, monitor conditions, balance the battery during charge / discharge and belongs to a large and diverse class of devices known in the world as BMS (Battery Manager System). The utility model can be used with efficient energy storage devices based on lithium-ion batteries for electric vehicles, UPS systems, off-grid storage devices, in stationary uninterruptible (emergency) power supply devices.

The main advantages when using this invention include: reduced charge time and increased battery discharge time. When discharged, less capacious cells will receive energy from more capacious ones, and when charged, less capacious cells will give off excess charge to more capacious cells. In this case, the capacity of the entire battery (in ampere-hours) will approximately correspond to the average capacity of all cells, and in watt-hours - the sum of watt-hours of all cells.

When charging the battery, not only the voltage of the cell, but also its internal resistance is taken into account. This allows you to speed up the process of charging the cell since avoids too early shutdowns of the memory due to the fact that the total voltage on the cell (which consists of the internal voltage of the cell plus internal resistance multiplied by the charging current) exceeds the threshold. When balancing batteries, a new technical solution is used that allows you to redistribute energy from more capacious cells to less capacious ones. The technical solution used allows achieving balancing currents three orders of magnitude higher than the balancing currents of traditional BMS (tens, hundreds of amperes versus tens and hundreds of milliamps). Also used technical solution gives a gain in energy consumption since the excess charge of the cell is not dissipated in the heating element, but is redistributed to other cells with high efficiency (90% and higher).

To achieve this result, a rechargeable battery was created, consisting of many cells, characterized in that the cells of the battery are connected in series by direct current, and by alternating current in parallel through a transformer balancing system. Moreover, each cell can be equipped with a DC to AC converter.

For the efficient operation of the battery, it is proposed to use a control system that comprises a general control unit and control units of each of a plurality of battery cells. Moreover, each cell of the set is controlled by its own unit, which may contain a microcontroller, configured to receive data on the state of the cell, transmit the received information to the general control unit, and balance the cell voltage with high currents (upon receipt of a control command from the general control unit). The balancing mode can work when charging, when the battery is low, and also in idle state.

It is assumed that the battery converters can be synchronized by a common control signal from the common control unit, or, depending on the state of the cell, the synchronous conversion of direct current to alternating current and vice versa from alternating to direct is carried out by a signal from the control system.

Below is a detailed description of the battery.

A rechargeable battery is a chain of series-connected cells or groups of parallel-connected cells (such groups are hereinafter referred to as a single cell of increased capacity). The battery current is the same for all cells, both during charging and during discharge, but since in the general case the capacity of the cells is different (due to technological variation or as a result of aging), the cells will come to full discharge (charge) at different times. In order for all cells to come to this point at the same time, it is necessary that the current in each cell depends on its capacity, and this is only possible with parallel connection of the cells.

The proposed solution allows you to connect cells simultaneously and in series and in parallel. By direct current, all cells are connected in series, and by alternating current - in parallel, through transformers. For this, each cell is equipped with an individual DC-to-AC converter, which enters the transformer and through it into the common balancing bus. The secondary windings of transformers from all cells are combined in parallel. All converters are synchronized by a common control signal. As long as there is a clock signal, the cells exchange energy with each other according to the principle of communicating vessels, those cells that have an increased potential, drain energy into the balancing bus, and the rest are fed from it. The process goes to the full potential equalization of the cells or to turn off the clock.

The device, in its basic configuration, consists of two types of blocks: general control cards and individual cell control cards. The number of the latter depends on the number of cells in the battery.

The general control board performs general functions to coordinate all actions performed on the battery. It is she who monitors the functioning of individual cells (she receives this information from control boards of individual cells) and decides what actions should be taken. A short list of what she does:

- allows or disables the charge mode, communicates with the charger and selects the correct charging current (if available in the charger);

- turns off the load when the battery is overdischarged;

- performs the functions of protecting the battery from emergency overloads and short circuits;

- in case of imbalance in the battery, it turns on the balancing mode and controls all individual cell management boards, synchronizing their work;

- If necessary, gives the engineer access to complete information about the state of the battery. Access is provided by connecting a computer to the SIAKB through a special program;

- implements light and sound alarms in case of emergency situations.

Single-cell control board executes the commands of the general control board. On it are the power elements that provide balancing the battery with high currents; these elements are also controlled by the general management board. The individual cell control board is responsible for the following functions:

- measurement of cell voltage;

- measurement of balancing current;

- Calculation of the charge of a cell leaked through the balancing circuit (required by the general control board to calculate the charge level of individual cells);

- transmission of measured and calculated information upon request to the general management board;

- signal transmission to the general control board in case the cell voltage exceeds the maximum permissible values.

- balancing the voltage of the cells at the command of the general control board.

In FIG. 1 shows a block diagram of a transformer balancing module for each cell. The module of each cell consists of the cell itself and the converter circuit, which consists of the keys K1 and K2 connected to the cell Cell1 through the windings L1 and L2 of the transformer T1. When the key K1 is closed, current begins to flow through the winding L1, while an EMF proportional to the cell voltage is induced in the winding L3. When the key K2 is closed, current flows through the winding L2, in the winding L3 an EMF is also induced, proportional to the cell voltage, but of opposite polarity. The keys K1 and K2 operate alternately under the control of an external clock signal, thus, at the terminals of the winding L3 there is an alternating voltage proportional to the cell voltage. The proportionality coefficient is set by the transformation coefficient of the transformer T1. If there is more than one module in the system and the terminals of the L3 windings of the modules are connected by a balancing bus (Fig. 2 shows a block diagram of a battery equipped with a transformer balancing system), then this bus will have a voltage proportional to the voltage of the cells with the highest potential, these cells will become donors, and the rest are recipients. For donors, the windings L1 and L2 will be primary, and the winding L3 will be secondary. In recipients, on the contrary, L3 is primary, and L1 and L2 are secondary, the keys K1 and K2 will act as synchronous rectifiers to power the recipient cell.

Through the balancing bus, all cells are connected in parallel and on an equal footing, that is, energy can flow from any cell to any other, the direction depends on the potential difference of the cells.

Unlike the world-famous balancing methods, the SIAKB is based on the transformer auto-balancing method, which consists in the following: a transformer and a synchronous rectifier connected to each of the battery cells of the battery, clocked from the Battery Control Module, and the secondary windings of the transformers are interconnected, combining the Modules Control Cells in a common system. This allows you to virtually connect in parallel all the cells of the battery to each other through alternating current. Which, in turn, allows balancing constantly in any operating mode of the battery. The principle of operation is based on the fact that the generated alternating voltages at the output of the secondary windings of the transformers will vary depending on the voltage of the cell to which the transformer is connected. And, accordingly, the balancing currents will flow from those transformers, the voltage on the secondary windings, which is higher, and flow into those whose voltages on the secondary windings are lower, due to which the battery cells will be balanced.

The main distinguishing feature of the proposed solution is that the system allows you to transfer the energy of the cell from any to any, and no matter what potential of the battery the cells of the donor and recipient are located. It is also worth highlighting the ability of the system to develop balancing currents of the order of 20-50 Amps at this stage of development. The balancing currents depend on the level of battery unbalance (the higher the unbalance, the higher the balancing current). That allows you to use balancing in any mode of battery operation, taking into account the estimated load currents of the battery and the required speed of balancing.

The power consumption of the system itself is minimal and comparable with the leakage currents of the batteries, which allows us to talk about the system efficiency of at least 90%.

According to the above classification of BMS, SUAKB at this stage of development, refers to the BMS with active balancing and voltage balancing algorithm.

The battery can be charged through the balancing bus, for this it is enough to apply the corresponding supply voltage to the balancing bus, coordinated in frequency and phase with the operation of the keys. This will be equivalent to connecting another cell to the balancing bus, but with infinite capacity and voltage corresponding to a fully charged cell. The currents of each cell will be different and depend on their state, while all cells will be charged in one time.

Battery discharge through the balancing bus is also possible. Since the voltage on the balancing bus does not depend on the number of cells in the battery, using one load device it will be possible to discharge the batteries with different total voltages, which can be convenient for carrying out CTZ (control and training cycles).

With sufficient power for transformers and keys, a transformer balancing system can replace one or more cells that are not in the battery for some reason. If the load currents are comparable to the balancing currents.

In an experimental setup consisting of two 200Ah cells connected only by a balancing bus, with a cell potential difference of 0.5 volts, the pumping current from one cell to another was 20-25 amperes.

By discharging one cell with a current of 20 A, the discharge current of the second cell, not connected to the load, was recorded. The current increased to 20 A as the first cell was discharged, and when the potential difference of the cells reached 0.5 volts, the discharge of the first cell almost stopped, since the discharge current was equal to the charge current coming from the second cell.

When charging one cell with a stable current of 20 A, the charge current of the second cell was not connected to the charger. The pumping current grew with the growth of the cell potential difference and when reaching 0.5 volts, the first cell almost stopped charging, since all the incoming current was pumped through the balancing bus to the second cell.

In FIG. 3 shows a general view of a transformer auto-balancing module.

A utility model has been disclosed above with reference to specific options for its implementation. For specialists, other embodiments of the utility model that do not change its essence, as disclosed in the present description, may be obvious. Accordingly, a utility model should be considered limited in scope only by the following utility model formula.

Claims (3)

1. The battery, consisting of many cells, characterized in that the cells of the battery in direct current are connected in series, and in alternating current in parallel through a transformer balancing system. 2. The battery according to claim 1, characterized in that each cell is equipped with a DC to AC converter. 3. The battery according to claim 1, characterized in that the converters are synchronized by a common control signal from the common control unit. .

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