CN113922455A

CN113922455A - Energy transfer type battery monomer voltage management circuit

Info

Publication number: CN113922455A
Application number: CN202111204763.4A
Authority: CN
Inventors: 尚德华; 张伟
Original assignee: Aopu Shanghai New Energy Co Ltd
Current assignee: Aopu Shanghai New Energy Co Ltd
Priority date: 2021-10-15
Filing date: 2021-10-15
Publication date: 2022-01-11
Anticipated expiration: 2041-10-15
Also published as: CN113922455B

Abstract

The invention relates to an energy transfer type battery monomer voltage management circuit, which is used for managing a battery pack comprising a plurality of battery monomers connected in series, wherein the battery pack is divided into a plurality of battery units, each battery unit comprises a plurality of battery rows connected in series, each battery row comprises a plurality of battery monomers, the management circuit comprises a transformer, a plurality of inductors, a plurality of energy storage capacitors and a plurality of switching tubes, the transformer is provided with a plurality of primary windings, two ends of a secondary winding of the transformer are respectively connected with the positive electrode and the negative electrode of the battery pack through the switching tubes, and the plurality of primary windings are respectively connected with two ends of the plurality of battery units in parallel through different switching tubes; two ends of each battery row are connected with an inductor in parallel through a switching tube, and an energy storage capacitor is connected in series between adjacent inductors connected with the battery rows in parallel in each battery unit. The energy transfer type battery monomer voltage management circuit improves the inconsistency of the battery pack and prolongs the service life of the battery.

Description

Energy transfer type battery monomer voltage management circuit

Technical Field

The invention relates to the technical field of battery management, in particular to an energy transfer type battery monomer voltage management circuit.

Background

The service life of the battery pack is seriously affected by the inconsistency of the batteries, and the battery pack is obviously inferior to the performance of a monomer in the aspects of cycle life, capacity utilization rate and the like according to the wooden barrel effect. Along with the recycling of the battery pack, the inconsistency of the monomers is aggravated, the grouping characteristic of the lithium ion battery is further worsened, and the overcharge and overdischarge conditions of a few monomers are easy to occur, so that the performance of the battery pack is greatly attenuated, even serious accidents such as combustion and explosion can occur under extreme conditions, and great obstruction is caused to the application and popularization of the lithium ion battery.

Carry out equalization control to the group battery, in the recycling process promptly, in order to energy consumption or the mode of shifting to in the group battery monomer energy in good time carry out the balance to reduce the monomer and take place the probability of overcharging and overdischarging, eliminate the adverse effect of depth of discharge difference to the group battery, and then improve the whole energy utilization of group battery, prolong battery cycle life.

Disclosure of Invention

In view of the above, it is desirable to provide an energy transfer type cell voltage management circuit capable of improving the inconsistency of the battery and prolonging the service life of the battery.

An energy transfer type battery cell voltage management circuit for managing a battery pack including a plurality of battery cells connected in series, the battery pack being divided into a plurality of battery cells, each battery cell including a plurality of battery banks connected in series, the battery banks including a plurality of battery cells,

the management circuit comprises a transformer, a plurality of inductors, a plurality of energy storage capacitors and a plurality of switching tubes, wherein the transformer is provided with a plurality of primary windings, two ends of a secondary winding of the transformer are respectively connected with the positive electrode and the negative electrode of the battery pack through the switching tubes, and the primary windings are respectively connected with two ends of the battery units in parallel through different switching tubes;

two ends of each battery row are connected with an inductor in parallel through a switching tube, and an energy storage capacitor is connected in series between adjacent inductors connected with the battery rows in parallel in each battery unit.

Furthermore, the management circuit further comprises a plurality of equalizing capacitors and a plurality of control switches, and the adjacent single batteries of the battery row are respectively connected with one equalizing capacitor in parallel through two control switches.

Furthermore, the management circuit further comprises a plurality of filter capacitors, and two ends of each battery monomer in the battery bank are connected with one filter capacitor in parallel.

Further, the number of battery rows in the plurality of battery units is equal, and the number of battery cells in the plurality of battery rows is equal.

Further, the battery unit has two battery rows therein.

Furthermore, an energy storage capacitor is connected in series between the adjacent inductors, and the energy storage capacitor and the adjacent inductors form a CUK converter.

Further, the battery row has two battery cells.

According to the energy transfer type battery cell voltage management circuit, rapid balancing of any cell in a battery pack can be achieved through transformer balancing, the control mode is simple, balancing current is large, balancing efficiency is high, the structure is easy to expand, the number of primary windings of a transformer is greatly reduced, and the difficulty in consistency control of the primary windings of the transformer is greatly reduced. When the balancing circuit of the CUK converters performs battery balancing, the balancing discharge and the charging are performed simultaneously, the balancing speed is high, the balancing energy transfer efficiency is high, the inductance in each CUK converter balances the voltage of the battery row formed by connecting a plurality of single batteries in series, so that the pressure difference is increased, and the defect that the balancing current is small when the voltage difference of each single battery in the battery pack is small is overcome. The switched capacitor method is used for managing active balance of two adjacent battery monomers, and mainly has the functions of judging the charge state difference between the two adjacent batteries, and transferring redundant electric quantity of a battery with high voltage to a battery with low voltage through a transfer station of a capacitor in a mode of switching a power supply by a balance module according to a balance algorithm result so as to realize the maximization of the battery capacity. The scheme only needs the switch and the capacitor to complete the construction of the equalizing circuit, and has the advantages of simple structure and almost no energy loss in the equalizing process. Through the combination of the equalization methods, the inconsistency of the battery pack battery is improved, and the service life of the battery is prolonged.

Drawings

Fig. 1 is a circuit diagram of an energy-transferring cell voltage management circuit according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in FIG. 1, an energy transfer type battery cell voltage management circuit is used for managing a battery cell B comprising a plurality of battery cells connected in series₁～B_nThe battery pack is divided into a plurality of battery units 110, each battery unit 110 comprises a plurality of battery rows 112 connected in series, and each battery row 112 comprises a plurality of battery cells. The management circuit comprises a transformer T and a plurality of inductors L₁～L_n/2A plurality of energy storage capacitors C_L1～C_Ln/4And a plurality of switching tubes S_1-1～S_1-n/2、S、S_N1～S_Nn/4The transformer T has a plurality of primary windings N_1-1～N_1-n/4Secondary winding N of transformer T₂The two ends of the primary winding are respectively connected with the positive electrode and the negative electrode of the battery pack through a switch tube S, and a plurality of primary windings N_1-1～N_1-n/4Respectively passing through different switch tubes S_N1～S_Nn/4And are connected to both ends of the plurality of battery cells 110. Two ends of each battery row 112 pass through a switch tube S_1-1～S_1-n/2An inductor is connected in parallel, and an energy storage capacitor C is connected in series between adjacent inductors connected in parallel with the battery row 112 in each battery unit 110_L1～C_Ln/4。

In this embodiment, the management circuit further includes a plurality of equalizing capacitors C_B1～C_Bn/2And a plurality of control switches S₁～S_nAdjacent battery cell B of the battery row 112₁～B_nRespectively through two control switches S₁～S_nConnected in parallel with an equalizing capacitor C_B1～C_Bn/2。

In this embodiment, the management circuit further includes a plurality of filter capacitors C₁～C_nTwo ends of each single battery in the battery row 112 are connected in parallel with a filter capacitor C₁～C_n. Specifically, the number of battery rows 112 in the plurality of battery units 110 is equal, and the number of battery cells in the plurality of battery rows 112 is equal. The battery unit 110 has two battery rows 112 therein. Adjacent inductance L₁～L_n/2An energy storage capacitor C is connected in series between_L1～C_Ln/4And adjacent inductance L₁～L_n/2Forming the CUK converter. The battery row 112 has two battery cells B₁～B_n。

This is explained in detail below with reference to fig. 1.

Taking an example of a serial module of n single batteries, according to the scheme of the present invention, every 4 single batteries constitute 1 battery unit 110, which is divided into n/4 units, every 2 single batteries constitute 1 battery row 112, and each battery unit 110 consists of 2 battery rows 112. For example battery cell B₁～B₄The 1 st battery unit and the battery monomer B are formed in series_n-3～B_nAre connected in series to form the (n/4) th battery unit. The 4 battery cells in each battery unit are divided into 2 small cells (battery rows), each battery row is composed of 2 battery cells, and the adjacent 2 battery rows share 1 CUK (Care Unite Skin, Cuk chopper circuit) converter equalization circuit. 2 battery monomers in each battery row share 1 capacitor as a balance capacitor; the battery unit composed of 4 battery cells composed of every 2 battery rows is balanced with the whole battery pack by arranging 1 transformer.

Wherein the switch tube S_1-1～S_1-n/2、S、S_N1～S_Nn/4And a control switch S₁～S_nIs a power switch tube. A filter capacitor C connected with each battery cell in parallel₁～C_nThe high-frequency filter capacitor is used for filtering noise waves in the energy transmission process. N is a radical of_1-1～N_1-n/4Primary winding for T-balancing of transformer, N₂And a secondary winding for equalizing the transformer. L is₁～L_n/2And C_L1～C_Ln/4Respectively an inductor and a capacitor of the equalizing circuit of the CUK converter. C_B1～C_Bn/2For equalising capacitanceEqualizing the capacitance.

The balancing principle of the circuit of the invention is that firstly, the transformer is used for completing the balancing between each battery unit 110 and the whole battery pack, then the CUK converter is used for completing the balancing between the adjacent 2 battery rows, and finally the balancing capacitor is used for completing the balancing between the 2 battery monomers in each battery row.

The specific equalizing process of the present invention will now be described in detail with respect to the 1 st battery cell 110 formed by the first 4 battery cells B1-B4 connected in series in the battery pack, and the equalizing steps are as follows:

in the first step, the balance between the 1 st battery unit 110 and the whole battery pack is accomplished by using the transformer T. The specific equalization process is divided into the following 2 cases to be respectively completed:

in the first case, assuming that the voltage of the 1 st cell is higher than that of the other cells in the battery pack, the equalization step is as follows:

step 1, power switch tube S_N1Conducting and switching on the 1 st battery unit and the primary winding N balanced by the transformer connected in series with the battery unit_1-1Part of the electric quantity of the battery unit is stored in the primary winding N_1-1In (1). The current direction is as in₁。

Step 2, power switch tube S_N1The power switch tube S is switched off, and the whole battery pack and a secondary winding N balanced by a transformer connected with the battery pack in series are switched on₂The previous step is stored in the primary winding N_1-1Is coupled to the secondary winding N₂Middle and secondary winding N₂The electric power in the battery pack flows to the whole battery pack. The current direction is as in₂。

In the second case, assuming that the voltage of the 1 st cell is lower than that of the other cells in the battery pack, the equalization step is as follows:

step 1, a power switch tube S is conducted to connect the whole battery module and a secondary winding N balanced by a transformer connected with the battery module in series₂Partial electric quantity of the whole battery module is stored in the secondary winding N₂In (1). The current direction is shown as i₃。

Step 2, the power switch tube S is turned off, and the power switch tube S_N1Conduction ofPrimary winding N equalized by connecting 1 st battery unit and transformer connected in series with it_1-1The last step is stored in the secondary winding N₂Is coupled to the primary winding N_1-1Middle primary winding N_1-1The amount of electricity in (1) is transferred to the 1 st battery cell. The current direction is shown as i₄。

And step two, completing the balance between the 1 st battery unit and the battery pack through a plurality of cycles of the first step, closing the transformer for balance, and starting the CUK converter for balance to complete the balance among 2 battery rows in the battery unit.

Now assume 2 cells B in the 1 st battery row₁～B ₂2 battery cells B compared with the 2 nd small battery unit₃～B₄The cell voltage is higher, and the equalization steps are as follows: see fig. 1.

Step 1, power switch tube S_1-1MOS transistor Q in_1-1And conducting to close the input and output loop. Power switch tube S_1-2In the body diode D_1-2And cutting off in the reverse direction. At this time, 2 battery cells B in the 1 st battery row₁～B₂The current I flowing out₁Make the inductance L₁Storing energy; energy storage capacitor C_L1Discharge current I₂Make the inductance L₂Storing energy and supplying to 2 single batteries B of the 2 nd battery row₃～B₄The battery is charged to transfer the amount of electricity. The discharging of the 1 st battery row and the charging of the 2 nd battery row are carried out simultaneously, and energy flows in two directions.

Step 2, power switch tube S_1-1MOS transistor Q in_1-1Cut-off, power switch tube S_1-2In the body diode D_1-2The current is conducted by positive bias, and an input-output loop is closed. At this time, 2 battery cells B in the 1 st battery row₁～B₂And an inductance L_1-1Induced electromotive force is added to the energy storage capacitor C_L1Charging, charging current I₃Energy storage capacitor C_L1Energy storage, inductance L₂Discharge energy, discharge current I thereof₄To 2 battery cells B of the 2 nd battery row₃～B₄The battery is charged to transfer the amount of electricity. Discharge of 1 st battery row and 2 nd electricityThe charging of the cell rows is carried out simultaneously, and the energy flows in two directions.

From the

above steps

1 and 2, it can be seen that the power switch tube S is used in any power switch tube_1-1MOS transistor Q_1-1During the on or off period, the 1 st battery row can transfer energy to the 2 nd battery row, and the energy storage capacitor C_L1In the circuit is an energy storage element. In the power switch tube S_1-1MOS transistor Q_1-1During the off period of (1), the current I of the 1 st cell row₃So that the energy storage capacitor C_L1Charging to store energy; in the power switch tube S_1-1MOS transistor Q_1-1During the on-period of (C), the energy storage capacitor_L1Discharging releases energy to the 2 nd battery bank.

If 2 battery cells B in the 1 st battery row₁～B₂Compared with 2 battery monomers B in the 2 nd battery row₃～B₄The cell voltage is lower and the equalization steps are similar to

steps

1 and 2 above.

And thirdly, completing the balance between the 1 st battery row and the 2 nd small battery row through a plurality of cycles of the second step, closing the CUK converter for balance, and starting the balance capacitor in each battery row to complete the balance between the 2 battery monomers in the battery row.

The equalization of the 1 st cell row will now be described as an example. The specific equalization process is as follows:

cell B in the 1 st battery row₁～B₂One of the cells must have a relatively high voltage, assuming cell B₁Comparative battery monomer B₂The voltage is higher. Make power switch tube S₁Conducting and connecting the battery cell B₁And an equalizing capacitor C_B1Part of the electric quantity of the battery unit is stored in the equalizing capacitor C_B1In (1). The current direction is shown as i₅。

Step 2, power switch tube S₁Closed, power switch tube S₂The MOS tube in the battery is closed, the body diode is conducted, and the battery monomer B is switched on₂Equalizing capacitor C connected in series with it_B1Equalizing capacitance C_B1The electric quantity stored in the last step is transferred to a battery monomer B₂In (1). Current squareTo the formula i in the figure₆。

And (4) completing the balance among 2 single batteries in the 1 st battery row through a plurality of cycles of the third step, finally closing the active balance of the capacitor, and finishing the balance of the whole series battery pack.

The general equalization strategy is that firstly, the transformer is used for equalizing and completing the active equalization of electric quantity transfer between each battery unit and the whole battery pack, then the CUK converter is used for equalizing and completing the active equalization of electric quantity transfer between 2 adjacent battery rows, and finally the equalization capacitor is used for completing the active equalization of electric quantity transfer between 2 battery monomers in each battery row.

The transformer balancing scheme can simultaneously realize the balancing of a plurality of battery monomers, so that the terminal voltages of all the battery monomers are close to the average voltage level finally. The topology has the advantages of simple operation and easy control, but when the number of the battery cells is large, the design of the multi-winding transformer is difficult, the consistency of the windings on the primary side is difficult to ensure, and the topology has the defect of difficult expansion. The whole battery pack is divided into a plurality of battery units, the battery units are connected with the primary windings of the transformers in units, after grouping transformer equalization is carried out, the number of the primary windings of the transformers is greatly reduced, for example, each battery unit is provided with four battery cells, the number of the primary windings of the transformers is 1/4 of the original number, and therefore the consistency control difficulty of the primary windings of the transformers is greatly reduced.

When the balancing circuit of the CUK converter is used for balancing the batteries, the balancing discharge and the charging are carried out simultaneously, the balancing speed is high, the balancing energy transfer efficiency is high, but usually only 2 adjacent battery monomers can be balanced, and the balancing principle is that the energy transfer balance is carried out by utilizing the voltage difference between the battery monomers, so that when the voltage difference of the battery monomers is small, the balancing current is small, and the balancing efficiency is very low. After the series single batteries are grouped, the inductance in each CUK converter is balanced by the voltage of the battery row formed by connecting the plurality of single batteries in series, and taking the example that each battery row is provided with two single batteries, the voltage balanced by the inductance is 2 times of the voltage of each single battery, namely the voltage difference between the single batteries is amplified by 2 times, so that the voltage difference is increased, and the defect that the balanced current is small when the voltage difference of each single battery in the battery pack is small is overcome.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. An energy transfer type battery cell voltage management circuit for managing a battery pack including a plurality of battery cells connected in series, the battery pack being divided into a plurality of battery cells, each battery cell including a plurality of battery banks connected in series, the battery banks including a plurality of battery cells,

2. The transferred battery cell voltage management circuit of claim 1, further comprising a plurality of balancing capacitors and a plurality of control switches, wherein adjacent battery cells of the battery row are respectively connected in parallel to one balancing capacitor through two control switches.

3. The transferred cell voltage management circuit of claim 1, further comprising a plurality of filter capacitors, one filter capacitor connected across each cell in the bank.

4. The transferred cell voltage management circuit of any of claims 1-3, wherein the number of battery rows in the plurality of battery cells is equal and the number of cells in the plurality of battery rows is equal.

5. The transferred cell voltage management circuit of claim 4, wherein there are two battery rows in the battery unit.

6. The transferred cell voltage management circuit of claim 5, wherein an energy storage capacitor is connected in series between adjacent inductors to form a CUK converter with the adjacent inductors.

7. The transferred cell voltage management circuit of claim 5, wherein there are two cells in the battery bank.