CN203859563U

CN203859563U - Pack to Cell equalization circuit based on LC resonant conversion

Info

Publication number: CN203859563U
Application number: CN201420264864.XU
Authority: CN
Inventors: 张承慧; 商云龙; 崔纳新; 纪祥
Original assignee: Shandong University
Current assignee: Shandong University
Priority date: 2014-05-22
Filing date: 2014-05-22
Publication date: 2014-10-01
Anticipated expiration: 2024-05-22

Abstract

The utility model discloses a Pack to Cell equalization circuit based on LC resonant conversion. The equalization circuit mainly comprises a microcontroller, a selector switch module, a general switch, an equalization bus, an LC resonance conversion and a filtering capacitor, a single cell with the lowest voltage in a battery pack is gated to the equalization bus and is connected with the output of the LC resonant conversion by the microcontroller, the general switch is controlled to be switched on so that an anode and a cathode of the battery pack are connected with the input of the LC resonant conversion, and the microcontroller sends a pair of PWM signals in complementary states to control the alternative operation of charging and discharging states of the LC resonant conversion so that zero-current switch equalization is realized. According to the Pack to Cell equalization circuit, the inconsistency between single cells is effectively improved, the equalization efficiency is improved, the equalization current is increased, the equalization time is reduced, the zero-current switch equalization is realized, the energy waste is reduced, the number of switches is reduced, and the circuit size and the cost are reduced.

Description

Pack to Cell equalization circuit based on LC resonance transformation

Technical Field

The utility model relates to a Pack to Cell equalizer circuit based on LC resonance transform.

Background

The energy crisis and environmental pollution are two major problems facing the world today. The electric automobile is popular with people in terms of energy conservation and environmental protection, and has become a necessary trend for automobile development in the future. Lithium ion batteries, due to their high energy density, low discharge rate and lack of memory effect, are widely used in electric vehicles and hybrid electric vehicles as power sources. However, due to the technical limitations of battery manufacturing technology and power management system, a large number of single batteries in multi-stage series-parallel connection are needed to provide sufficient supply voltage and driving power during the use of the power battery. However, when such batteries are used in series, the phenomena of overcharge and overdischarge of some battery cells are easily caused by the problem of capacity imbalance, which greatly affects the service life and safety of the power battery pack. Therefore, it is necessary to perform balance management on the battery packs. Obviously, as one of the key technologies of the battery management system, effective balancing of the series battery pack has become a research hotspot.

Currently, equalization mainly includes three major categories, namely dissipative equalization, non-dissipative equalization and battery selection.

The dissipative type equalization (also called battery bypass equalization) realizes the equalization of the battery voltage by connecting a dissipative device in parallel to each battery cell in the battery pack for discharging and shunting. Dissipative balancing is further divided into two categories: passive equalization and active equalization. The dissipation balance structure and control is simple and low in cost, but has the problems of energy waste and thermal management.

The non-dissipative balancing adopts capacitors, inductors and the like as energy storage elements, common power conversion circuits are used as topology bases, and a scattered or concentrated structure is adopted to realize a unidirectional or bidirectional balancing scheme. Depending on the energy flow, the non-dissipative balancing can be divided into four categories: (1) cell to Cell; (2) cell to Pack; (3) pack to Cell; (4) cell to Pack to Cell. For the Cell to Cell balancing method, energy can be directly transferred from the battery Cell with the highest voltage to the battery Cell with the lowest voltage, the Cell to Cell balancing method has higher balancing efficiency and is suitable for high-voltage application, but the voltage difference between the battery cells is reduced, and the on-state voltage drop of a power electronic device is caused, so that the balancing current is very small, and therefore, the Cell to Cell balancing method is not suitable for a large-capacity power battery. In the Pack to Cell balancing method, each balancing is to supplement energy to the battery Cell with the lowest voltage through the battery Pack, so that large balancing current can be realized, and the Pack to Cell balancing method is suitable for large-capacity power batteries. The non-dissipative balancing has the problems of complex circuit structure, large volume, high cost, long balancing time, high switching loss and the like.

The battery selection balance refers to that battery monomers with consistent performance are selected through experiments to construct a battery pack, and generally a two-step screening process is adopted. Firstly, selecting battery monomers with similar average battery capacity under different discharge currents; and secondly, selecting the battery monomers with similar battery voltage variation under different SOC through pulse charging and discharging experiments in the battery monomers screened in the first step. Because the self-discharge rates of the single batteries are different, the battery selection balance is not enough to keep the battery pack balanced all the time in the whole life cycle of the battery. It can only be used as a complementary equalization method to other equalization methods.

The main reasons why the conventional equalization method is not suitable for the lithium ion battery are as follows:

1) the open circuit voltage of the lithium ion battery is relatively flat when the SOC is between 30% and 70%, even if the SOC is greatly different, the corresponding voltage difference is small, and in addition, because the conduction voltage drop exists in the power electronic device, the balance current is small, and even the power electronic device can not be normally conducted;

2) due to the conduction voltage drop of the power electronic device, zero voltage difference equalization is difficult to realize among the battery monomers.

The Chinese patent application (application number 201310278475.2) of the invention provides a zero-current switch active equalization circuit of a power battery and an implementation method thereof, which can judge the highest and lowest voltage battery monomers in a battery pack in real time, perform zero-current switch equalization on the battery monomers, and perform peak clipping and valley filling on two battery monomers with the largest voltage difference in the battery pack in each equalization, thereby greatly improving the equalization efficiency and effectively reducing the inconsistency among the battery monomers. However, the used power electronic devices have conduction voltage drop, so that zero voltage difference between the battery cells is difficult to achieve, the balance current is small, and the balance time is long.

For this reason, the chinese utility model application (application No. 201320660950.8) and the chinese patent application (application No. 201310507016.7) propose a Cell to Cell battery equalization circuit based on Boost transformation and soft switch, the utility model uses a Boost transformation to Boost the battery Cell with the highest voltage in the battery pack to a higher voltage, so as to realize the large current, zero voltage difference equalization; and the zero-current switching balance is realized by using LC resonance transformation, so that the energy waste is reduced, and the balance efficiency is improved. However, the main problems with this utility model are: due to the fact that the Cell-to-Cell type equalization circuit belongs to the Cell-to-Cell type equalization circuit, even if Boost conversion is used, the improved equalization current is limited, the equalization requirement of a large-capacity power battery of an electric automobile can not be met far away, and energy waste also exists in the Boost conversion.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problems, the utility model provides a Pack to Cell equalizer circuit based on LC resonance transform, including microcontroller, balanced generating line, LC resonance transform, selection switch module, master switch, power battery group and filter capacitance, this equalizer circuit can realize that the battery group is balanced to the free zero current switch of battery through using an LC resonance transform, has reduced the energy waste, has improved balanced efficiency; the large current balance can be obtained, and the method is suitable for rapid balance of large-capacity power batteries; and the problem that the traditional equalizing circuit is difficult to realize zero voltage difference between the single batteries is solved.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a Pack to Cell equalizer circuit based on LC resonance transform, which comprises a microcontroller, the balanced generating line, LC resonance transform, the selector switch module, the master switch, power battery group and filter capacitance, wherein, microcontroller passes through each battery monomer of voltage detection circuit connection group battery, battery monomer passes through the selector switch module and connects balanced generating line, LC resonance transform circuit's output is connected to balanced generating line, the group battery passes through master switch and connects LC resonance transform circuit's input, microcontroller passes through drive circuit connection control LC resonance transform circuit, microcontroller passes through multichannel gating switch and connects selector switch module and master switch.

The input end and the output end of the LC resonance conversion circuit are respectively connected with a filter capacitor in parallel;

the microcontroller comprises an analog-to-digital conversion module, a Pulse Width Modulation (PWM) signal output end and a general input/output (IO) end;

the analog-to-digital conversion module is connected with the single battery through the voltage detection circuit and is used for converting a voltage signal of the single battery into a digital signal so as to determine the single battery with the lowest voltage;

the pulse width modulation PWM signal output end is connected with the LC resonance conversion circuit through a driving circuit and is used for generating a control driving signal of an MOS tube switch;

the universal IO end is connected with the selection switch module through a multi-path gating switch and used for decoding a battery number corresponding to the lowest single voltage determined by the microcontroller and controlling the selection switch module to gate the battery single with the lowest voltage at any position in the battery pack to the balancing bus; meanwhile, the general IO end is connected with the main switch through a multi-path gating switch, and the main switch is controlled to connect the positive electrode and the negative electrode of the battery pack to the input of the LC resonance conversion circuit.

The LC resonance conversion circuit comprises four MOS tubes, four diodes, an inductor and a capacitor, wherein one end of the input end is connected with one MOS tube M₁Series diode D₁Then, two branches are connected, one branch is connected with MOS tube M in series₃And a diode D₃The other path is connected with an inductor L and a capacitor C in series, and the other end of the input end is reversely connected with a diode D₂Connecting MOS tube M₂Two branches are connected at the back, one branch is connected with the other end of the capacitor C, and the other branch is reversely connected with a diode D₄Rear connection MOS tube M₄. MOS transistor M in LC resonance conversion circuit₁And M₂Driven by a PWM + signal, MOS transistor M₃And M₄Driven by another PWM signal with reverse state, diode D₁～D₄The reverse current limiting function is realized.

The LC resonance transformation works in two states of charging and discharging under the drive of two complementary PWM signals.

The charging state is that LC resonance transformation is connected with the positive electrode and the negative electrode of the battery pack in parallel.

The discharge state is that LC resonance transformation is connected with the battery monomer with the lowest voltage in parallel.

The two filter capacitors are respectively connected in parallel with the input end and the output end of the LC resonance transformation and are used for filtering high-frequency alternating current into direct current so as to reduce the damage to the battery.

The utility model discloses a theory of operation does:

the microcontroller controls the selection switch module through the decoding of the universal IO end according to the battery monomer number corresponding to the lowest monomer voltage, and gates the battery monomer with the lowest voltage at any position in the battery pack to the balance bus; then, the microcontroller controls the main switch to be closed to take the total voltage of the whole battery pack as the input of LC resonance conversion, so that the problem that zero voltage difference among battery monomers is difficult to realize due to conduction voltage drop of a power electronic device is solved, and energy loss caused by boosting conversion and boosting by using Boost is eliminated; meanwhile, the microcontroller sends a pair of PWM signals with complementary states to control LC resonance transformation, so that the LC resonance transformation alternately works in a charging state and a discharging state. Particularly, when the PWM frequency sent by the microcontroller is equal to the inherent resonant frequency of LC resonant transformation, zero-current switching equalization can be realized, and each equalization is realized by transferring energy from the whole battery pack to the battery cell with the lowest voltage in the battery pack, so that the equalization current is increased, and the equalization efficiency is improved.

The utility model has the advantages that:

(1) compared with a Cell to Cell type equalizing circuit, n switches are reduced, and the circuit volume and the cost are reduced;

(2) the problem that zero voltage difference among battery monomers is difficult to realize due to conduction voltage drop of a power electronic device is effectively solved;

(3) the large-current balance can be realized, and the method is suitable for large-capacity power batteries;

(4) zero-current switching balance is realized, and energy waste is reduced;

(5) the inconsistency among the battery monomers is effectively improved, and the balancing efficiency is improved.

Drawings

Fig. 1 is a schematic diagram of the Pack to Cell equalization circuit based on LC resonant transformation according to the present invention;

fig. 2 is a working principle diagram of the LC resonance transformation charging state of the present invention;

FIG. 3 is a schematic diagram of the LC resonance transformation of the discharge state of the present invention;

FIG. 4 shows that the LC resonance transformation of the present invention is under the resonance condition for the charging and discharging current i and the capacitor voltage V_CSchematic waveform diagrams of (1);

FIG. 5 shows the charging/discharging current i and the capacitor voltage V in the resonant state of LC resonance transformation obtained by experiment_CFig. 5(a) is a waveform diagram of a Cell to Cell type equalizer circuit, and fig. 5(b) is a waveform diagram of a Pack to Cell type equalizer circuit;

fig. 6 is a diagram of the equalizing effect of the power battery in the static state.

The specific implementation mode is as follows:

the present invention will be further explained with reference to the accompanying drawings and examples.

As shown in fig. 1 to 6, a Pack to Cell type equalization circuit based on LC resonance transformation includes a microcontroller, a selection switch module, a main switch, an equalization bus, LC resonance transformation and a filter capacitor, the microcontroller is connected with the selection switch module, the main switch, the LC resonance transformation and a battery Cell, the positive and negative electrodes of a battery Pack are connected with the input of the LC resonance transformation through the main switch, the output of the LC resonance transformation is connected with the selection switch module through the equalization bus, the selection switch module is connected with each battery Cell, and the input and the output of the LC resonance transformation are connected in parallel with the two filter capacitors; wherein,

the analog-to-digital conversion module is connected with the single batteries through the voltage detection circuit and is used for converting voltage signals of the single batteries into digital signals so as to determine the voltage of each single battery and the serial number corresponding to the single battery with the lowest voltage;

the pulse width modulation PWM signal output end is connected with LC resonance transformation through a driving circuit and is used for generating a control driving signal of an MOS tube switch;

the universal IO end is connected with the selection switch module through a multi-path gating switch and used for decoding a battery number corresponding to the lowest single voltage determined by the microcontroller and controlling the selection switch module to gate the battery single with the lowest voltage at any position in the battery pack to the balancing bus; meanwhile, the general IO end is connected with the main switch through a multi-path gating switch, and the main switch is controlled to connect the positive electrode and the negative electrode of the battery pack to the input of LC resonance transformation.

The LC resonance conversion circuit comprises four MOS tubes, four diodes, an inductor and a capacitor, wherein one end of the input end is connected with one MOS tube M₁Series diode D₁Then, two branches are connected, one branch is connected with MOS tube M in series₃And a diode D₃Another circuit is connected with inductor L and capacitor C in series, and the other end of input end is invertedDiode D₂Connecting MOS tube M₂Two branches are connected at the back, one branch is connected with the other end of the capacitor C, and the other branch is reversely connected with a diode D₄Rear connection MOS tube M₄. MOS transistor M in LC resonance conversion circuit₁And M₂Driven by a PWM + signal, MOS transistor M₃And M₄Driven by another PWM signal with reverse state, diode D₁～D₄The reverse current limiting function is realized.

When the frequency of the PWM signal is equal to the inherent resonant frequency of LC resonant transformation, the balancing circuit realizes zero current switch balancing between the battery units with the lowest voltage by the battery pack.

An implementation method of the Pack to Cell type equalization circuit based on LC resonance transformation comprises the following steps:

(1) obtaining the voltage of a battery monomer: the microcontroller acquires the voltage of each monomer of the power battery by means of the analog-to-digital conversion module;

(2) judging the voltage: the microcontroller calculates the maximum monomer voltage difference according to the acquired monomer voltage of the battery, and if the difference is greater than a battery equalization threshold value, the equalization circuit is started, and the serial number of the battery monomer corresponding to the lowest monomer voltage is determined;

(3) gating the battery: the microcontroller decodes the battery monomer number corresponding to the lowest monomer voltage through the decoding circuit, and controls the selection switch module to gate the battery monomer corresponding to the lowest monomer voltage to the balancing bus;

(4) energy transfer: the microcontroller controls the conduction of the main switch to connect the positive end and the negative end of the battery pack with the input of the LC resonance transformation, and simultaneously controls the four MOS tubes of the LC resonance transformation to enable the LC resonance transformation to work in two states of charging and discharging alternately, thereby realizing the continuous transmission of energy.

In the step (4), when the LC resonance transformation is connected with the whole battery pack in parallel, the battery pack charges the LC resonance transformation; when the LC resonance transformation is connected with the battery monomer with the lowest voltage in parallel, the LC resonance transformation charges the battery monomer, and energy is transferred from the whole battery pack to the battery monomer with the lowest voltage along with the charging and discharging processes of the LC resonance transformation.

The first embodiment is as follows:

take 8 battery cells as an example, and assume B₃The battery cell with the lowest voltage is used.

A microcontroller of the equalizing circuit selects a digital signal processing DSP (TMS320F28335), and has high-precision AD sampling and PWM output; the multi-channel gating switch adopts CD4051, is a single 8-channel digital control analog electronic switch, has A, B and C binary control input ends anda total of 4 inputs with low on-resistance and very low off-leakage current; the voltage detection circuit adopts a voltage measurement chip special for LTC6802 of Linte company to measure the voltage of each battery in the battery pack in real time.

The selection switch module adopts a relay with a pair of normally open contacts, the model number of the relay is HJR1-2C L-05V, and the relay is shown in figure 1 (S)_i，Q_i) And (i-1, 2,3 …, n) is a pair of normally open switches. The microcontroller is controlled to conduct or close by a multiplexer switch CD 4051.

The LC resonance circuit consists of four MOS tubes M₁～M₄Four diodes D₁～D₄And an inductor L and a capacitor C. Wherein M is₁、M₂、D₁、D₂L, C form a charging loop; m₃、M₄、D₃、D₄And L, C form a discharge circuit. M₁Source electrode, D₂The negative electrodes of the battery pack are respectively connected with the positive electrode and the negative electrode of the battery pack through the main switch; d₃Negative electrode of (1), M₄The source electrodes of the equalizing buses are respectively connected with the positive electrode and the negative electrode of the equalizing bus. Diode D₁～D₄And plays a role of isolation. MOS transistor M₁～M₄Driven by a pair of complementary PWM signals from a microcontroller DSP, where M₁And M₂Driven by a PWM + signal, M₃And M₄Driven by the other way of PWM signals with complementary states. When M is₁And M₂On, M₃And M₄When the circuit is switched off, the LC resonance circuit works in a charging state; when M is₃And M₄On, M₁And M₂When turned off, the LC resonant circuit operates in a discharge state. In this way, energy can be transferred from the battery pack to the battery cell with the lowest voltage through the continuous charging and discharging of the LC resonance circuit, and particularly, zero-current switching equalization is realized when the PWM frequency sent by the microcontroller is equal to the inherent resonance frequency of the LC quasi-resonance circuit.

Firstly, the microcontroller acquires the voltage of each monomer of the power battery by means of the analog-to-digital conversion module, thereby determining the lowest voltage of the monomers and the corresponding serial number of the battery monomers, judging whether the maximum voltage difference is greater than the battery equalization threshold value of 0.02V, starting the equalization circuit if the maximum voltage difference is greater than the battery equalization threshold value, and gating the switch module by a decoding chip CD4051 (S)₄、Q₄) And a main switch (S)₀、Q₀) Keeping the conduction state of the battery until the balance is finished, and enabling the battery monomer B with the lowest voltage₃And gating to the equalizing bus, and gating the input ends of the battery pack and the LC resonant circuit.

Under the equilibrium state, the microcontroller controls the LC resonant circuit to alternately work in a charging state and a discharging state, thereby realizing the continuous transmission of energy.

When M is shown in FIG. 2₁And M₂When conducting, M₃And M₄And the LC resonant circuit is switched off and is connected with the battery pack in parallel. The battery pack, the inductor L and the capacitor C form a resonant loop, the capacitor C is charged at the moment, the resonant current i is positive, and the voltage V at the two ends of the capacitor C_cStarts to rise until the resonant current i becomes negative, as can be seen from fig. 4, V_cThe hysteresis resonance current i is one quarter of a cycle, and the waveforms are all sine waves. At this moment, due to M₃And M₄In the off state, the battery cell B₃Is open and therefore flows into B₃Current i of_B3Is zero; because of the filter capacitor C₁There is no other discharging loop in parallel connection with two ends of the battery pack, so the resonance current i flowing into the LC is the current i flowing out of the battery pack_batAnd the specified current flowing out of the battery cell/battery pack is positive, so that a battery pack current i shown as an operating state i in fig. 4 can be obtained_batAnd B₃Current i_B3And (4) waveform.

When M is shown in FIG. 3₃And M₄When conducting, M₁And M₂Off, the LC resonance circuit passes through the selection switch module (S)₄、Q₄) With the lowest voltage cell B₃And (4) connecting in parallel. B is₃L and C form a resonant circuit, at which time the capacitor C discharges, the resonant current i is negative, and the voltage V across the capacitor C_cStarts to drop until the resonant current becomes positive. Since the battery is in an open state, the current i flowing out of the battery_BatIs zero; at the same time, the resonance current i at the moment is B₃So that a battery current i as shown in state ii of fig. 4 can be obtained_batAnd B₃Current i_B3And (4) waveform.

As shown in FIG. 5, the charging/discharging current i and the capacitor voltage V in the resonant state for the LC resonance transformation obtained by the experiment_CWherein fig. 5(a) is a waveform diagram of Cell to Cell type equalization circuit, fig. 5(b) is a waveform diagram of Pack to Cell type equalization circuit, and the comparison shows that, the utility model discloses a Pack to Cell type equalization circuitThe Cell type equalization circuit has an equalization current value far higher than that of the Cell toCell type equalization circuit, and the equalization efficiency is greatly improved.

As shown in fig. 6, the equilibrium effect diagram of the power battery in the static state of the power battery of the present invention is shown when the initial voltage of the battery cell is B₀＝2.709V，B₁＝2.701V，B₂＝2.694V，B₃＝2.698V，B₄＝3.301V，B₅＝3.302V，B₆＝3.299V，B₇When the voltage is 3.300V, the equalizing circuit only needs about 3500s, and the maximum voltage difference of the battery cells in the battery pack is close to 0.

Although the present invention has been described with reference to the accompanying drawings, it is not intended to limit the scope of the present invention, and those skilled in the art should understand that various modifications or variations that can be made by those skilled in the art without inventive work are still within the scope of the present invention.

Claims

1. A Pack to Cell equalization circuit based on LC resonance transformation is characterized in that: the intelligent power battery pack comprises a microcontroller, an equalizing bus, LC resonance transformation, a selection switch module, a main switch, a power battery pack and a filter capacitor, wherein the microcontroller is connected with each battery monomer of the battery pack through a voltage detection circuit, the battery monomers are connected with the equalizing bus through the selection switch module, the equalizing bus is connected with the output end of the LC resonance transformation circuit, the battery pack is connected with the input end of the LC resonance transformation circuit through the main switch, the microcontroller is connected with the LC resonance transformation circuit through a driving circuit, and the microcontroller is connected with the selection switch module and the main switch through a multi-path gating switch.

2. The LC resonant transformation-based Pack to Cell equalization circuit of claim 1, wherein: and the input end and the output end of the LC resonance conversion circuit are connected with a filter capacitor in parallel.

3. The LC resonant transformation-based Pack to Cell equalization circuit of claim 1, wherein: the microcontroller comprises an analog-to-digital conversion module, a Pulse Width Modulation (PWM) signal output end and a general input/output (IO) end;

the analog-to-digital conversion module is connected with the single batteries through the voltage detection circuit and is used for converting voltage signals of the single batteries into digital signals so as to determine the voltage of each single battery and the battery number corresponding to the single battery with the lowest voltage;

the universal IO end is connected with the selection switch module through a multi-path gating switch and used for decoding a battery number corresponding to the lowest single voltage determined by the microcontroller and controlling the selection switch module to gate the battery single with the lowest voltage at any position in the battery pack to the balancing bus; meanwhile, the general IO end is connected with the main switch through a multi-path gating switch, and the main switch is controlled to gate the positive electrode and the negative electrode of the battery pack to the input of the LC resonance conversion circuit.

4. The LC resonant transformation-based Pack to Cell equalization circuit of claim 1, wherein: the LC resonance conversion circuit comprises four MOS tubes, four diodes, an inductor and a capacitor, wherein one end of the input end is connected with one MOS tube M₁Series diode D₁Then, two branches are connected, one branch is connected with MOS tube M in series₃And a diode D₃The other path is connected with an inductor L and a capacitor C in series, and the other end of the input end is reversely connected with twoPolar tube D₂Connecting MOS tube M₂Two branches are connected at the back, one branch is connected with the other end of the capacitor C, and the other branch is reversely connected with a diode D₄Rear connection MOS tube M₄。

5. The LC resonant transformation-based Pack to Cell equalization circuit as claimed in claim 4, wherein: the MOS transistor M in LC resonance conversion₁And M₂Driven by a PWM + signal, MOS transistor M₃And M₄Driven by another PWM signal with the state reverse, and under the drive of the PWM signal with the two complementary states, the LC resonance transformation works in two states of charging and discharging.

6. The LC resonant transformation-based Pack to Cell equalization circuit of claim 5, wherein: the charging state is that LC resonance transformation is connected with the positive electrode and the negative electrode of the battery pack in parallel.

7. The LC resonant transformation-based Pack to Cell equalization circuit of claim 5, wherein: the discharge state is that LC resonance transformation is connected with the battery monomer with the lowest voltage in parallel.