CN204794291U - Battery management system's dynamic equalizer circuit - Google Patents
Battery management system's dynamic equalizer circuit Download PDFInfo
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- CN204794291U CN204794291U CN201520430804.5U CN201520430804U CN204794291U CN 204794291 U CN204794291 U CN 204794291U CN 201520430804 U CN201520430804 U CN 201520430804U CN 204794291 U CN204794291 U CN 204794291U
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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Abstract
The utility model provides a battery management system's dynamic equalizer circuit, including connecting the cascaded two -way DC -DC converter in proper order between external power source and battery cell group, polarity reverser and battery select switch group, still including connecting a cascaded voltage sample switch block in proper order and the AD converter between battery cell group and CPU's a AD port, still including the in proper order cascaded two AD converter of connection between two -way DC -DC converter and CPU's the 2nd AD port and the redundant voltage acquisition circuit of optoelectronic isolation ware component, detect each battery cell voltage by embedded control software, and it judges to carry out the redundancy to two voltages that same battery cell gathered, whether start subsequent balanced battery management with the decision. The utility model discloses a circuit is simple, and dynamic A balanced approach is practical, can obviously improve battery cell voltage detecting's accuracy, is showing to reduce the balanced battery management of the mistake that is leaded to by monomer voltage acquisition mistake.
Description
Technical field
The utility model relates to battery management, particularly relates to a kind of dynamic equalization circuit of battery management system.
Background technology
The battery pack that the novel battery comprising lithium ion battery is composed in series, because battery cell exists inconsistency, can cause the active volume of whole battery pack to diminish during use; Voltage higher battery cell charging time can cause charging process premature termination, charging capacity is diminished; Again can guiding discharge process premature termination during the battery cell electric discharge of low voltage, discharge capacity is reduced.At battery management system (Batterymanagementsystem, initialism is BMS) in equalizer or equalizing circuit module are set, equilibrium is carried out to battery cell, monomer high for voltage is discharged, the monomer low to voltage charges, and the voltage of each monomer in battery pack and capacity and charge-discharge characteristic are reached unanimity.The applicant has announced " a kind of method for dynamically balancing of battery management system and dynamic equalization circuit thereof " at first patent CN101917047B, belong to energy transfer bidirectional equalization method, at the two-way high frequency switch power converter of BMS internal control one, high-energy monomer battery core is transferred to low-yield monomer battery core, energy loss can be reduced to greatest extent, and effectively make up the otherness of battery, realize high-effect management.
The general principle figure of energy transfer bidirectional equalization circuit as shown in Figure 1, comprise the bidirectional, dc/direct current (DirectCurrent of the cascade successively between the cell B1 ~ B4 being connected to external power source and sequential series, initialism is DC) converter, polarity reverser, and number of switches is than the battery selector switch K1 ~ K5 for controlling the corresponding cell of gating of the cell quantity many 1 of the battery B1 ~ B4 of sequential series, the number of switches voltage sampling switches S1 ~ S5 for control gating corresponding cell equal to battery selector switch quantity of the cascade successively between the A/D port also comprising cell B1 ~ B4 and the CPU being connected to sequential series, and the first analog/digital (Analog/Digital, initialism is A/D) converter, odd number battery selector switch K1, K3, one end of K5 and the negative output terminal of described polarity reverser i.e. negative collection bus is connected, even number battery selector switch K2, one end of K4 is connected with the positive output end of described polarity reverser and positive collection bus, odd number battery selector switch K1, K3, the other end of K5 is connected with the positive pole of a cell, the even number battery selector switch K2 of more than odd number 1, the other end of K4 is connected with the negative pole of a cell, odd number voltage sampling switches S1, S3, one end of S5 is connected with the positive input terminal of a described A/D converter, even number voltage sampling switches S2, one end of S4 is connected with the negative input end of a described A/D converter, odd number voltage sampling switches S1, S3, the other end of S5 is connected with the positive pole of a cell, the even number voltage sampling switches S2 of more than adjacent odd number 1, the other end of S4 is connected with the negative pole of same cell, described battery selector switch K1 ~ K5 and described voltage sampling switches S1 ~ S5 is by the CPU centralized control being provided with embedded Control software.
Its method for dynamically balancing comprises the following steps:
1) by the voltage of each cell in the battery B1 ~ B4 of embedded Control software detection sequential series;
2) item of the cell too low or too high for voltage needing independent charge or discharge is judged by CPU;
3) control command is sent by CPU, control the corresponding voltage sampling switches S1 ~ S5 of gating, each cell is selected to be linked into the input port of an A/D converter successively, collected the voltage parameter of each cell successively by port the one A/D port A/D1 of CPU after A/D conversion, when CPU detects that the voltage of certain monomer battery voltage and other cells is inconsistent by contrast, just start balancing battery management, certain adjacent two of controlling in gating corresponding battery selector switch K1 ~ K5 close, cell inconsistent for voltage is linked into described polarity reverser and carries out polarities match, be resent to described bidirectional DC-DC converter, two-way DC/-DC converter operative orientation is controlled by CPU, positive collection bus is accessed by needing the cell too low or too high for voltage of independent discharge and recharge, negative collection bus charge or discharge, realize energy trasfer,
4) step 1 is repeated) ~ 3), until the voltage of each cell in the battery B1 ~ B4 of sequential series, within the scope of the permissible error of setting, reaches energy content of battery dynamic equalization.
This method for dynamically balancing can reduce charge and discharge device number of devices and the complexity in circuits of battery management system, but, foregoing circuit has certain defect, when there is the fault that such as electric conduction resistive is large in voltage sampling switches, monomer voltage will be caused to gather mistake, and this mistake of CPU self None-identified, mistake starts balancing battery management, its consequence shortens the capacity of battery, shorten battery life, more seriously directly damage battery, therefore, be necessary to increase and redundancy determination is carried out to monomer voltage, to ensure correct balancing battery management.
Existing method of carrying out redundancy determination is increase by tunnel independently redundancy voltage collection circuit, Fig. 2 is the increase in the schematic block circuit diagram of the active equalization battery management of redundancy voltage acquisition function, it is the redundancy voltage collection circuit increasing an autonomous channel on the basis of the energy transfer bidirectional equalization circuit of Fig. 1, comprise one group of voltage sampling switches S11 ~ S51, select each cell to the input port of the 2nd A/D converter successively, collected the voltage of each cell successively by the 2nd A/D port A/D2 of CPU after A/D conversion, CPU carries out redundancy determination to the first voltage of same cell and the second voltage, contrast the numerical value of the first voltage and the second voltage, if the default value that numerical difference is greater than setting is the threshold value of 10mv, now alarm monomer battery voltage sampling is abnormal, start balancing battery management.This method is multiplied the quantity of voltage sampling switches and polar selecting switch, and circuit is too complicated, is necessary further improvement.
Summary of the invention
Technical problem to be solved in the utility model makes up the above-mentioned defect at first patent " a kind of method for dynamically balancing of battery management system and dynamic equalization circuit thereof ", provides a kind of dynamic equalization circuit of battery management system of improvement.
Technical problem of the present utility model is solved by the following technical programs.
The dynamic equalization circuit of this battery management system, comprise the bidirectional, dc/direct current (DirectCurrent of the cascade successively between the cell group being connected to external power source and sequential series, initialism is DC) converter, polarity reverser, and number of switches is than the battery selector switch group for controlling the corresponding cell of gating of the cell quantity many 1 of the battery pack of sequential series, also comprise the number of switches voltage sampling switches group for control gating corresponding cell equal to battery selector switch quantity of the cascade successively between cell group and an A/D port of CPU being connected to sequential series, and the first analog/digital (Analog/Digital, initialism is A/D) converter, one end of odd number battery selector switch and the negative output terminal of described polarity reverser i.e. negative collection bus is connected, one end of even number battery selector switch is connected with the positive output end of described polarity reverser and positive collection bus, the other end of odd number battery selector switch is connected with the positive pole of a cell, the other end of the even number battery selector switch of more than odd number 1 is connected with the negative pole of a cell, one end of odd number voltage sampling switches is connected with the positive input terminal of a described A/D converter, one end of even number voltage sampling switches is connected with the negative input end of a described A/D converter, the other end of odd number voltage sampling switches is connected with the positive pole of a cell, the other end of the even number voltage sampling switches of more than adjacent odd number 1 is connected with the negative pole of same cell, described battery selector switch group and described voltage sampling switches group are by the CPU centralized control being provided with embedded Control software, each monomer battery voltage in the battery pack of described embedded Control software detection sequential series, and judge the item of the cell too low or too high for voltage needing independent discharge and recharge, send corresponding control command, by bidirectional DC-DC converter, polarity reverser is by positive collection bus, negative collection bus carries out reversal and polarities match, and control bidirectional DC-DC converter operative orientation, positive collection bus is accessed by needing the cell too low or too high for voltage of independent discharge and recharge, negative collection bus charge or discharge, realize energy trasfer, until the every batteries voltage of each single battery voltage in the battery pack of each group sequential series is within the scope of the permissible error of setting, reach energy content of battery dynamic equalization.
The feature of the dynamic equalization circuit of this battery management system is:
Also comprise the redundancy voltage collection circuit for preventing voltage acquisition mistake that the 2nd A/D converter of the cascade successively between the 2nd A/D port being connected to described bidirectional DC-DC converter and CPU and photoisolator form, described one end of 2nd A/D converter connects with the positive output end of described bidirectional DC-DC converter and the balanced positive bus-bar of monomer, the described other end of the 2nd A/D converter connects with the negative output terminal of described bidirectional DC-DC converter and the balanced negative busbar of monomer, by each monomer battery voltage in the battery pack of embedded Control software detection sequential series, comprise: CPU by be connected to its A/D port by described voltage sampling switches, first voltage of each cell in the battery pack of a described A/D converter acquisition order series connection, CPU also by be connected to its 2nd A/D port by the 2nd A/D converter of described battery selector switch, described polarity reverser, successively cascade and photoisolator form for prevent the redundancy voltage collection circuit acquisition order of voltage acquisition mistake from connecting battery pack in the second voltage of each cell, CPU also carries out redundancy determination to the first voltage of same cell and the second voltage, if the numerical difference of contrast detection first voltage and the second voltage is greater than the threshold value of setting, alarm redundancy voltage acquisition mistake, does not start follow-up balancing battery management, if the numerical difference of contrast detection first voltage and the second voltage is not more than the threshold value of setting, just start follow-up balancing battery management.
Technical problem of the present utility model is solved by following further technical scheme.
Described CPU is single-chip microcomputer, one in digital signal processor and microprocessor, for gathering the monomer battery voltage of two separate passages, and comparing difference, judge the item of the cell too low or too high for voltage needing independent charge or discharge, and the control cell the highest to voltage discharges, the cell minimum to voltage charges, by high-energy monomer battery core is transferred to low-yield monomer battery core, energy loss can be reduced to greatest extent, monomer battery voltage is reached unanimity, make up the otherness of battery, realize high-effect management.
Preferably, the microprocessor of described CPU to be model be MC9S08DE6, its direct voltage gathered is 0 ~ 3.3V.
Described voltage sampling switches is the withstand voltage solid state relay for 400vdc, and its life-span is long, withstand voltage height, and switch speed is fast, for switching the cell needing acquisition channel.
Preferably, the solid state relay of described voltage sampling switches to be model be AQY214S.
The mos field effect transistor (Metal-Oxide-SemiconductorField-EffectTransistor, initialism is MOSFET) of described battery selector switch to be model be AON7400A.
A described A/D converter is high-accuracy instrument differential operational amplifier.
Preferably, the high-accuracy instrument differential operational amplifier of a described A/D converter to be model be AD620.
Described 2nd A/D converter is high-accuracy instrument operational amplifier.
Preferably, the high-accuracy instrument operational amplifier of described 2nd A/D converter to be model be OP07C.
Described photoisolator is precision photoelectric coupler.
Preferably, the precision photoelectric coupler of described photoisolator to be model be HCPL7800.
The cell quantity basis embody rule of the cell group of described sequential series is at least 5.
Adopt the method for dynamically balancing of battery management system of the present utility model, comprise the following steps:
1) by each monomer battery voltage in the battery pack of embedded Control software detection sequential series;
2) item of the cell too low or too high for voltage needing independent charge or discharge is judged by CPU;
3) control command is sent by CPU, control gating corresponding polar selecting switch group and collection bus is carried out reversal, control the corresponding battery selector switch group of gating simultaneously and carry out polarities match, and control two-way isolated converter operative orientation, by needing the cell too low or too high for voltage of independent discharge and recharge to be linked into charge or discharge in collection bus, realize energy trasfer;
4) step 1 is repeated) ~ 3), until each monomer battery voltage in the battery pack of sequential series is within the scope of the permissible error of setting, reach dynamic equalization.
The feature of the method for dynamically balancing of this battery management system is:
Described step 1) by each monomer battery voltage of embedded Control software detection, comprising:
CPU is by being connected to the first voltage of each cell in the battery pack of being connected by described voltage sampling switches, a described A/D converter acquisition order of its A/D port;
CPU also by be connected to its 2nd A/D port by the 2nd A/D converter of described battery selector switch, described polarity reverser, successively cascade and photoisolator form for prevent the redundancy voltage collection circuit acquisition order of voltage acquisition mistake from connecting battery pack in the second voltage of each cell;
CPU also carries out redundancy determination to the first voltage of same cell and the second voltage, to determine whether start follow-up balancing battery management.
By the exception of redundancy determination Timeliness coverage monomer battery voltage, correctness and the reliability of monomer battery voltage detection can be significantly improved, significantly reduce the mistake balancing battery management caused by monomer voltage collection mistake.
Described step 1) carry out redundancy determination and be, if the numerical difference of contrast detection first voltage and the second voltage is greater than the threshold value of setting, alarm redundancy voltage acquisition mistake, does not start follow-up balancing battery management; If the numerical difference of contrast detection first voltage and the second voltage is not more than the threshold value of setting, just starts follow-up balancing battery management, enter step 2).
The default value of the threshold value of described setting is 10mv.
The utility model beneficial effect is compared with prior art:
The utility model carries out redundancy determination at a small amount of parts that only increase on the basis of first patent CN101917047B of the applicant to the voltage of cell, circuit is simple, method for dynamically balancing is practical, correctness and the reliability of monomer battery voltage detection can be significantly improved, significantly reduce the mistake balancing battery management caused by monomer voltage collection mistake.
Accompanying drawing explanation
Fig. 1 is the schematic block circuit diagram of existing active equalization battery management;
Fig. 2 is the existing schematic block circuit diagram adding the active equalization battery management of redundancy voltage acquisition function;
Fig. 3 is the schematic block circuit diagram of the utility model embodiment.
Embodiment
Contrast accompanying drawing below in conjunction with embodiment the utility model is described.
A kind of dynamic equalization circuit of battery management system as shown in Figure 3, comprise the bidirectional DC-DC converter of the cascade successively between the cell B1 ~ B4 being connected to external power source and sequential series, polarity reverser, and for controlling the battery selector switch K1 ~ K5 of the corresponding cell of gating, voltage sampling switches S1 ~ the S5 for controlling the corresponding cell of gating of the cascade successively between the A/D port A/D1 also comprising cell B1 ~ B4 and the CPU being connected to sequential series, and an A/D converter, odd number battery selector switch K1, K3, one end of K5 and the negative output terminal of polarity reverser i.e. negative collection bus is connected, even number battery selector switch K2, one end of K4 is connected with the positive output end of polarity reverser and positive collection bus, odd number battery selector switch K1, K3, the other end of K5 is connected with the positive pole of a cell, the even number battery selector switch K2 of more than odd number 1, the other end of K4 is connected with the negative pole of a cell, odd number voltage sampling switches S1, S3, one end of S5 is connected with the positive input terminal of an A/D converter, even number voltage sampling switches S2, one end of S4 is connected with the negative input end of an A/D converter, odd number voltage sampling switches S1, S3, the other end of S5 is connected with the positive pole of a cell, the even number voltage sampling switches S2 of more than adjacent odd number 1, the other end of S4 is connected with the negative pole of same cell, battery selector switch group and voltage sampling switches group are by the CPU centralized control being provided with embedded Control software, each monomer battery voltage in the battery pack of embedded Control software detection sequential series, and judge the item of the cell too low or too high for voltage needing independent discharge and recharge, send corresponding control command, by bidirectional DC-DC converter, polarity reverser is by positive collection bus, negative collection bus carries out reversal and polarities match, and control bidirectional DC-DC converter operative orientation, positive collection bus is accessed by needing the cell too low or too high for voltage of independent discharge and recharge, negative collection bus charge or discharge, realize energy trasfer, until the every batteries voltage of each single battery voltage in the battery pack of each group sequential series is within the scope of the permissible error of setting, reach energy content of battery dynamic equalization.The MCU of CPU to be model be MC9S08DE6, its direct voltage gathered is 0 ~ 3.3V, the solid state relay of voltage sampling switches S1 ~ S5 to be model be AQY214S, the MOSFET of battery selector switch K1 ~ K5 to be model be AON7400A, the high-accuracy instrument differential operational amplifier of an A/D converter to be model be AD620.
Also comprise the redundancy voltage collection circuit for preventing voltage acquisition mistake that the 2nd A/D converter of the cascade successively between the 2nd A/D port A/D2 being connected to bidirectional DC-DC converter and CPU and photoisolator form, one end of 2nd A/D converter connects with the positive output end of bidirectional DC-DC converter and the balanced positive bus-bar of monomer, and the other end of the 2nd A/D converter connects with the negative output terminal of bidirectional DC-DC converter and the balanced negative busbar of monomer.The high-accuracy instrument operational amplifier of the 2nd A/D converter to be model be OP07, the precision photoelectric coupler of photoisolator to be model be HCPL7800.
Adopt the method for dynamically balancing of the dynamic equalization circuit of the battery management system of this embodiment, comprise the following steps:
1) by each monomer battery voltage in the battery B1 ~ B4 of embedded Control software detection sequential series, comprising:
CPU is by being connected to the first voltage of each cell in the battery B1 ~ B4 connected by described voltage sampling switches, a described A/D converter acquisition order of its A/D port;
CPU also by be connected to its 2nd A/D port by the 2nd A/D converter of described battery selector switch, described polarity reverser, successively cascade and photoisolator form for prevent the redundancy voltage collection circuit acquisition order of voltage acquisition mistake from connecting battery B1 ~ B4 in the second voltage of each cell;
CPU also carries out redundancy determination to the first voltage of same cell and the second voltage, to determine whether start follow-up balancing battery management;
If the default value that the numerical difference of contrast detection first voltage and the second voltage is greater than setting is the threshold value of 10mv, alarm redundancy voltage acquisition mistake, do not start follow-up balancing battery management;
If the default value that the numerical difference of contrast detection first voltage and the second voltage is not more than setting is the threshold value of 10mv, just starts follow-up balancing battery management, enter step 2);
2) item of the cell too low or too high for voltage needing independent charge or discharge is judged by CPU;
3) control command is sent by CPU, control gating corresponding polar selecting switch group and collection bus is carried out reversal, control the corresponding battery selector switch group of gating simultaneously and carry out polarities match, and control two-way isolated converter operative orientation, by needing the cell too low or too high for voltage of independent discharge and recharge to be linked into charge or discharge in collection bus, realize energy trasfer;
4) step 1 is repeated) ~ 3), until each monomer battery voltage in the battery B1 ~ B4 of sequential series is within the scope of the permissible error of setting, reach dynamic equalization.
This embodiment can significantly improve correctness and the reliability of monomer battery voltage detection, significantly reduces the mistake balancing battery management caused by monomer voltage collection mistake.
Above content is in conjunction with concrete preferred implementation further detailed description of the utility model, can not assert that concrete enforcement of the present utility model is confined to these explanations.For the utility model person of an ordinary skill in the technical field; make some equivalent alternative or obvious modification without departing from the concept of the premise utility; and performance or purposes identical, all should be considered as belonging to the scope of patent protection that the utility model is determined by submitted to claims.
Claims (7)
1. the dynamic equalization circuit of a battery management system, comprise the bidirectional DC-DC converter of the cascade successively between the cell group being connected to external power source and sequential series, polarity reverser, and number of switches is than the battery selector switch group for controlling the corresponding cell of gating of the cell quantity many 1 of the battery pack of sequential series, also comprise the number of switches voltage sampling switches group for control gating corresponding cell equal to battery selector switch quantity of the cascade successively between cell group and an A/D port of CPU being connected to sequential series, and an A/D converter, one end of odd number battery selector switch and the negative output terminal of described polarity reverser i.e. negative collection bus is connected, one end of even number battery selector switch is connected with the positive output end of described polarity reverser and positive collection bus, the other end of odd number battery selector switch is connected with the positive pole of a cell, the other end of the even number battery selector switch of more than odd number 1 is connected with the negative pole of a cell, one end of odd number voltage sampling switches is connected with the positive input terminal of a described A/D converter, one end of even number voltage sampling switches is connected with the negative input end of a described A/D converter, the other end of odd number voltage sampling switches is connected with the positive pole of a cell, the other end of the even number voltage sampling switches of more than adjacent odd number 1 is connected with the negative pole of same cell, described battery selector switch group and described voltage sampling switches group are by the CPU centralized control being provided with embedded Control software, it is characterized in that:
Also comprise the redundancy voltage collection circuit for preventing voltage acquisition mistake that the 2nd A/D converter of the cascade successively between the 2nd A/D port being connected to described bidirectional DC-DC converter and CPU and photoisolator form, described one end of 2nd A/D converter connects with the positive output end of described bidirectional DC-DC converter and the balanced positive bus-bar of monomer, and the described other end of the 2nd A/D converter connects with the negative output terminal of described bidirectional DC-DC converter and the balanced negative busbar of monomer.
2. the dynamic equalization circuit of battery management system as claimed in claim 1, is characterized in that:
Described CPU is the one in single-chip microcomputer, digital signal processor and microprocessor.
3. the dynamic equalization circuit of battery management system as claimed in claim 1, is characterized in that:
Described voltage sampling switches is the withstand voltage solid state relay being at least 400vdc.
4. the dynamic equalization circuit of battery management system as claimed in claim 1, is characterized in that:
The MOSFET of described battery selector switch to be model be AON7400A.
5. the dynamic equalization circuit of battery management system as claimed in claim 1, is characterized in that:
A described A/D converter is high-accuracy instrument differential operational amplifier.
6. the dynamic equalization circuit of battery management system as claimed in claim 1, is characterized in that:
Described 2nd A/D converter is high-accuracy instrument operational amplifier.
7. the dynamic equalization circuit of battery management system as claimed in claim 6, is characterized in that:
Described photoisolator is precision photoelectric coupler.
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107306037A (en) * | 2016-04-18 | 2017-10-31 | 西安电子科技大学昆山创新研究院 | A kind of cell voltage supervisory circuit and method |
CN108595060A (en) * | 2018-02-13 | 2018-09-28 | 友达光电股份有限公司 | Touch sensing device |
CN110768336A (en) * | 2019-11-12 | 2020-02-07 | 中国船舶重工集团公司第七一九研究所 | Control method of supplementary electric battery management circuit additionally provided with discharge module |
DE102021212816A1 (en) | 2021-11-12 | 2023-05-17 | Vitesco Technologies GmbH | Method and device for balancing battery cells of a battery module |
CN117595466A (en) * | 2024-01-18 | 2024-02-23 | 杭州高特电子设备股份有限公司 | Dual-redundancy acquisition monitoring battery active equalization system and control method |
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2015
- 2015-06-23 CN CN201520430804.5U patent/CN204794291U/en active Active
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107306037A (en) * | 2016-04-18 | 2017-10-31 | 西安电子科技大学昆山创新研究院 | A kind of cell voltage supervisory circuit and method |
CN108595060A (en) * | 2018-02-13 | 2018-09-28 | 友达光电股份有限公司 | Touch sensing device |
CN110768336A (en) * | 2019-11-12 | 2020-02-07 | 中国船舶重工集团公司第七一九研究所 | Control method of supplementary electric battery management circuit additionally provided with discharge module |
CN110768336B (en) * | 2019-11-12 | 2023-04-07 | 中国船舶重工集团公司第七一九研究所 | Control method of supplementary electric battery management circuit additionally provided with discharge module |
DE102021212816A1 (en) | 2021-11-12 | 2023-05-17 | Vitesco Technologies GmbH | Method and device for balancing battery cells of a battery module |
CN117595466A (en) * | 2024-01-18 | 2024-02-23 | 杭州高特电子设备股份有限公司 | Dual-redundancy acquisition monitoring battery active equalization system and control method |
CN117595466B (en) * | 2024-01-18 | 2024-05-14 | 杭州高特电子设备股份有限公司 | Dual-redundancy acquisition monitoring battery active equalization system and control method |
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Address after: 518057, Shenzhen, Guangdong province Nanshan District hi tech Park North Qi Road, 2, Qing Bang electronic building B Building 5, building 6, floor Patentee after: Ke Lie technical concern Co., Ltd of Shenzhen Address before: 518057 Guangdong city of Shenzhen province Nanshan District Pine Hill Qi Min Road No. 1 Betel building on the third floor Patentee before: Ke Lie technical concern Co., Ltd of Shenzhen |