• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    System for management, diagnosis and interconnection of several batteries of propulsion of an electric vehicle, in which each battery (1) integrates a group of cells (11) that connects with a management system (bms) and a series of communication interfaces with the rest of the system, a discharge connection (17) and a charging connection (16) through which the corresponding charger (7) is connected; a power manager (2) that receives the energy from each battery (1) and transmits it to the motor controller (3) that sends it to the motor (5) through a power stage (34), according to the commands of the user and the restrictions imposed by the control unit (4), which is responsible for managing the entire system and determines how energy is consumed according to its management algorithms and user requests; a communication bus (bus) serves as a data link between all the units of the system. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2640749A1
    申请号:ES201630567
    申请日:2016-05-02
    公开日:2017-11-06
    发明作者:Javier MELLADO HORCAS;Borja ROJAS GUILLAMA
    申请人:Torrot Electric Europa SL;
    IPC主号:
    专利说明:

    DESCRIPTION

    Management system, diagnosis and interconnection of several propulsion batteries of an electric vehicle.
     5
    Object of the invention

    The present invention describes an electrical and electronic system for the management of the propulsion (powertrain) of an electric vehicle, which also integrates an integrated electronic diagnostic system of all the units that compose it. 10 It also has output of operating data and diagnosis abroad, so that it allows communication with both the user and the technical service.

    Background of the invention

    Electric vehicles are equipped with at least one drive motor, which uses electric power from a group of batteries interconnected with each other and mounted on the vehicle itself. Although the characteristics of the batteries used in the same electric vehicle are usually similar, there may be 20 different types of batteries, as well as differences in the level of electrical energy that they are capable of storing or in the parameters that affect them, how can the self discharge current be. These differences cause that in the repetition of cycles of load and discharge some batteries accumulate charge over the rest and that others discharge more than the due. 25

    To extend the life of the batteries as much as possible, it is advisable to keep the batteries at all times within the manufacturer's specifications, which normally consist of cell voltage levels between a maximum and a minimum value. This is especially important in certain types of batteries, such as 30 lithium batteries, whose useful life can be greatly reduced if they are charged or discharged too much.

    In the patent literature we find for example the document WO2015181420 in which a system is described that measures the charge of each battery, its temperature and the charge / discharge current that crosses it, and in
    Based on this data, it decides whether it is necessary to dissipate part of the energy supplied to a particular battery during a charging operation, or to take other measures. In document EP270158 a protection device against current overcurrent in a vehicle battery is detailed.
     5
    Description of the invention

    In general, the systems that have been described refer to protection devices that come from other sectors in which batteries were used, other than the automotive sector and we are not aware of the disclosure of 10 management and diagnostic systems that allow User decide which batteries will be used according to their status, in addition to telling the motor controller how to manage the power according to the available energy and the conditions of the batteries at all times.
     fifteen
    The system of the invention constantly evaluates these conditions for efficient energy management. Variables are also controlled electrical and mechanical safety and useful data are generated for the user and the technical service.

    It also presents communications functions necessary for sending data 20 in an organized way to the user and the technical service, so that it can monitor the operation of the system, access statistics of use of your vehicle, access the diagnosis, provide a service Agile to the user when diagnosing, sending spare parts, etc.
     25
    Brief description of the drawings

    The features and advantages of the invention will become more clearly apparent from the detailed description. The details, both in the description and in the preferred embodiment, are given by way of example, referring to a possible case of practical realization, but it is not limited to the details set forth herein, and therefore this description should be considered from an illustrative point of view and without limitation of any kind. In these sections, the numbering mentioned refers to the figures that are attached in this document, in which: 35

    Figure 1 shows a functional block diagram of the devices that make up this management, diagnosis and interconnection system of several propulsion batteries of an electric vehicle.

    Figure 2 represents a more detailed scheme than the previous one, in which the 5 different devices that make up this system have been represented in their most essential components.

    Preferred embodiment of the invention.
     10
    As shown in Figure 1, the system of the invention has the following basic devices:

    a) A series of batteries (1), which can be of different types, each of which integrates a group of cells (11) that connects with a management system 15 (BMS) and a series of communications interfaces with the rest of the system, a discharge connector (17) and a charging connector (16) through which the corresponding charger (7) is connected.

    b) A power manager (2) that receives the energy from each battery (1) and sends it to the motor controller (3) and to the remaining units of the system: For each battery (1) it comprises an input channel (21 ) and a power switch (22) that enables or disables the corresponding battery power from the control unit (4).
     25
    c) A motor controller (3) that sends the power to the motor (5) through a power stage (34) according to the user's orders and the restrictions imposed by the control unit (4), which has a User control module (33) that receives direct orders from the system and transmits them to a processor (31) that generates the appropriate signals for motor control (5), 30 as well as alarm and statistics signals and communicates them to a ECU engine control unit (4);

    d) An engine control unit (ECU) (4) that manages the entire system and determines how energy is consumed based on its management algorithms 35 and user requests; which includes a processor (42) that receives the mode change requests and if admissible, sends the change order to the
    motor controller (3) and also collects and displays on a display (41) diagnostic and operating data of all system components; in addition to a series of communications interface with a user terminal (46), with the system bus (BUS) and with OBD diagnostic devices;
     5
    e) Finally, the system includes a communications bus (BUS) that serves as a data link between all units, for the operation of the system.

    A more detailed representation of each of these devices has been made in Figure 2. 10

    The batteries (1) can be of different types, integrating all of them in an integrated electronic management device, in charge of the electrical protection of each one of them and of the estimation of the current state of the same, of the diagnosis of errors and of the Calculation of usage statistics. The functions are distributed in the following elements:

     A group of cells (11) connected in series and parallel depending on the desired power and energy, which is present in each of the batteries (1). twenty

     A management system (BMS) (20) in each of the batteries, which performs the following functions:
    o Electrical protections (13) against overloads, short circuits, temperatures out of range, loss of insulation, detection of internal wiring breakage, etc.
    o Power switches (14), responsible for allowing or cutting the charge and discharge of the battery.
    o It also contains an interface with the communications bus (15) so that it can present data to the control unit. 30
    o Calculation of battery states, estimating the charge stored in the battery and the energy available in the battery through current sensors (12), cell voltage (19) and temperature.
    o Calculation of usage statistics.
    o Generation of errors and alarm states, which will be communicated to the ECU via the system bus.

     Each battery integrates a series of connectors with the rest of the system; namely:
    o A discharge connector (17), which sends the power to the power management
    o A charging connector (16), by which the individual charger 5 is connected to the battery (7).
    o A communications connector that allows the battery connection with the system communications bus.

    The power management device (2) is the unit responsible for receiving power 10 from each battery (1), and sending the set of received power to the motor controller (3) through the DC Bus and the other units They consume energy. It is divided into different elements:

     One input channel (21, 24, 27) per battery is the connection of the battery to the management module.

     A power switch (22, 25, 28). For batteries without charge-discharge control by communications bus, the power management allows to enable or disable the power of each of the batteries 20 individually from the control unit (4).

     An anti-noise mechanism (23, 26, 29) that prevents uncontrolled currents flowing between batteries, for each channel.
     25
    The motor controller (3) sends the power to the motor (5) according to the user's orders and the restrictions imposed by the control unit (4). It has integrated diagnosis and communications via bus with the rest of the system.

     Through an interface (33) it receives signals from the user's controls (62), 30 for example through the accelerator and the brakes the user tells the propulsion system what to do, since it is the most direct way of sending of orders to the system ..

     A processor (31) that performs several important tasks: 35
    o Read directly from the interface (33) the user controls to know the requests for power, braking, etc.
    o It is connected to a communications interface that communicates with the control unit (4) through the system bus, receiving mode change commands, with which it is possible to switch from one more power mode to another saving mode. energy, for example.
    o With all the information from the previous two points, it generates the 5 signals suitable for motor control, with which it connects through a power stage (34).
    o The processor is responsible for processing the different alarm states and communicating them to the ECU (4), so that it can offer diagnostic data abroad. 10

    An engine control unit (ECU) (4) is responsible for managing the entire system, deciding how energy will be consumed based on its management algorithms and user requests. This unit incorporates the following devices: 15

     A display (41) in which it presents data to the user in real time, is the most direct form of communication with the system.

     A processor (42) that performs the following functions: 20
    o Controls all communications of the propulsion system through the system bus (BUS).
    o Receive the mode change requests through a command (61) and if it is admissible, send the change order to the motor driver.
    o Collect error data of all the components of the propulsion system to be able to present diagnostic data outside in an orderly manner.
    o Control the display.
    o Manage keyless start functions.
    o Controls the power management module (2). 30

     This unit includes a wireless communications interface (43) that allows operating data, partial diagnosis for users, complete diagnosis for technical service, OBD over wireless protocols, etc. to be communicated through an application for Smartphone / Tablet / PC . 35

     A communication interface (45) is responsible for communicating with the system bus, which allows the internal operation of the propulsion system, isolated from wireless communications and the OBD system.

     It also includes the interface (44) with standard OBD 5 I / II diagnostic devices (47).

    A communications bus (BUS) is the one that establishes the data link between all units for system operation.
     10
    The basic operation of the machine is as follows: When the system starts, the electronic control unit (4) has the ability to communicate with the different batteries (1) connected to the bus. In this way you can decide which batteries will be used according to their status, in addition to telling the motor controller (3) how to manage the power, according to the available energy and the conditions of the batteries 15 at any time. It is not necessary that all batteries are connected and charged for proper operation, nor that they are all at the same level of charge.

    The system also supports manual selection of the power mode, provided that the electronic control unit (4) considers that the selected mode can be used without problems. The normal operation of the system constantly evaluates these conditions to make efficient energy management. Electrical and mechanical safety variables are also controlled and useful data is generated for the user and the technical service: 25
     Battery voltage, current and temperature.
     Battery charge status.
     Remaining autonomy.
     Energy consumption.
     Alarm states 30
     Voltage, current and temperature of the motor controller.
     Controller alarm states.
     Controller operating modes.
     Engine temperature and speed.
     Anti-theft and anti-tamper systems. 35
     Kilometers traveled.
     Stored errors.
     Other usage statistics.

    Both the electronic management of each battery (1) and the motor controller (3), the motor (5), the power management unit (2) and the electronic control unit 5 (4) all have a diagnosis of sensors, actuators and all its internal elements. This data is sent to the electronic control unit U through the bus (BUS), which presents the data abroad through different standard protocols: OBD, etc. This allows the diagnosis of the propulsion system through the use of a standard tool, or with specific applications from the manufacturer.

    In addition, this system has implemented a series of communications functions necessary for sending data in an organized way to the user and the technical service. fifteen
     By OBD protocol over wired bus, as usual in automotive.
     Via CAN Bus or Bluetooth to a specific service application, with advanced functions only available to authorized personnel.
     Via Bluetooth to a Smartphone or Tablet. Through an application, the user can view the operation of the system, access usage statistics of their vehicle, access the diagnosis, etc.
     Through an application, the control unit is able to send diagnostic and operating data directly to the technical service through the data connection of the phone or tablet, so that an agile service can be provided to the user at the time to diagnose, send spare parts, etc.



     30

    权利要求:
    Claims (1)
    [1]

    1.- Management system, diagnosis and interconnection of several propulsion batteries of an electric vehicle, which admits batteries (1) of different types, characterized in that it comprises: 5
    a) a set of batteries (1), each of which includes the following elements:
     a group of cells (11) in each of the batteries (1), consisting of a series and parallel cell connection depending on the desired power and energy; 10
     a management system (BMS) for each of the batteries, which includes a current sensor (12), a processor (13) that has circuit protection functions, manages the switches (14) responsible for controlling the load and The battery discharge also contains an interface (15) with the communications bus that provides data to the control unit of the motor (4) and performs the calculation of battery status, usage statistics and error generation and status alarm Y
     a series of communication interfaces with the rest of the system, including a download connector (17), which sends the energy to the power management; a charging connector (16) through which the charger (7) is connected to the battery and a communications connector (18), which allows the battery to be connected to the system's communications bus;
    b) a power manager (2) that receives the energy from each battery and is responsible for sending the energy received to the motor controller (3) and to the remaining units 25 of the system which, for each battery (1), is divided in different elements:
     an input channel (21) that connects the battery (1) to the management module (2),
     a power switch (22) that allows to enable or disable the corresponding battery power from the control unit, and
     an anti-noise device (23) that prevents uncontrolled currents 30 from circulating between the batteries;
    c) a motor controller (3) that sends the power to the motor (5) through a stage (34) according to the user's orders and the restrictions imposed by the control unit (4), which has integrated diagnostics and a communications interface (32) to the system bus (BUS); which integrates: 35
     a user control module (33) that receives direct orders from the system through the accelerator and the brakes (62) through which the user indicates to the propulsion system the actions to be taken;
     a processor (31) that:
    • directly read the user controls (33) to know the 5 power or braking requests;
    • communicates through an interface (32) with the motor control unit (4) through the system bus, receiving orders to change mode, from more power to another for energy saving, or vice versa,
    • with the information received from the previous two points, it generates the 10 signals suitable for motor control (5) through a power unit (34), and
    • generates alarm signals and controller statistics and communicates the different alarm states to the motor control unit (4);
    d) an engine control unit (ECU) (4) that manages the entire system and determines how energy is consumed based on its management algorithms and user requests; which includes:
     a display (41) of presentation of data to the user in real time,
     a processor (42) that controls the communications of the propulsion system through the system bus (BUS), receives the mode change requests and if it is admissible, sends the change order to the motor controller; collects error data from all components of the propulsion system by presenting diagnostic data, manages keyless start functions, and controls the power management module;
     a wireless communications interface (43) through which the system communicates with a user terminal (46) to transmit operating data, diagnosis,…
     a communication interface (45) with the system bus that allows the internal operation of the propulsion system, and
     a communications interface (44) with OBD 30 diagnostic devices (47); Y
    e) a communications bus (BUS) that serves as a data link between all units, for the operation of the system.
      35
    类似技术:
    公开号 | 公开日 | 专利标题
    ES2320895T3|2009-05-29|PROCEDURE TO CONTROL ENERGY FLOWS.
    KR100906907B1|2009-07-08|Car battery management system
    CN108583478B|2020-10-09|Low-battery control method and system
    EP2769872B1|2019-11-27|Hybrid battery system for an electric vehicle
    KR101755894B1|2017-07-19|Apparatus for preventing over discharge of vehicle battery and method thereof
    ES2379280T3|2012-04-24|Semiconductor switch module, double direction, self-protective, high current and low losses and operating method
    US20050077874A1|2005-04-14|Battery power source apparatus of electric car
    CN108068652A|2018-05-25|It battery recharge notification and recharges automatically
    CN102180096A|2011-09-14|Method of monitoring vehicle batteries
    JP2011067047A|2011-03-31|Battery system
    ES2640749B1|2018-08-23|SYSTEM OF MANAGEMENT, DIAGNOSIS AND INTERCONNECTION OF VARIOUS BATTERIES OF PROPULSION OF AN ELECTRIC VEHICLE
    US20130274975A1|2013-10-17|Diversion of energy from regenerative braking
    US20160303992A1|2016-10-20|Electrified Vehicle Predictive Low-Voltage Battery Alert
    US10991994B2|2021-04-27|Temperature monitoring apparatus and method for battery pack
    JP2005324784A|2005-11-24|Power supply for automobile
    US10800284B2|2020-10-13|Charging strategies to mitigate lithium plating in electrified vehicle battery
    US10300806B2|2019-05-28|Vehicle and method for controlling a battery in a vehicle
    ES2552364B1|2016-11-03|Electronic management system for monitoring and control of lithium batteries
    JP2005312276A|2005-11-04|Condition monitor for onboard storage battery
    JP6530136B2|2019-06-12|Parallel monitoring device for battery pack status
    JP6790617B2|2020-11-25|Electric vehicle
    JP6191699B2|2017-09-06|Battery pack and battery pack control method
    US11265811B2|2022-03-01|Method of monitoring and controlling an onboard system and a monitor and control system
    CN211787415U|2020-10-27|Multifunctional automobile alarm device
    ES2377399B1|2013-02-04|SYSTEM AND PROCEDURE FOR BATTERY CHARGING MANAGEMENT OF AN ELECTRIC VEHICLE.
    同族专利:
    公开号 | 公开日
    AR107941A1|2018-06-28|
    WO2017191339A1|2017-11-09|
    EP3466742A4|2020-03-11|
    EP3466742B1|2022-01-19|
    EP3466742A1|2019-04-10|
    ES2640749B1|2018-08-23|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20070090803A1|2005-10-20|2007-04-26|Han-Seok Yun|Method of estimating state of charge for battery and battery management system using the same|
    CN202080273U|2011-03-30|2011-12-21|重庆长安汽车股份有限公司|Energy management system of battery electric vehicle|
    US20130020970A1|2011-07-18|2013-01-24|O2Micro, Inc.|Control System and Control Method for Electric Bicycle|
    WO2015181420A1|2014-05-26|2015-12-03|Jofemar, S.A.|Electronic management system for monitoring and controlling lithium batteries|
    US20150369867A1|2014-06-24|2015-12-24|Toyota Jidosha Kabushiki Kaisha|Battery management terminal and battery management system|
    CA2818450C|2013-06-17|2020-04-07|Mcmaster University|Reconfigurable hybrid energy storage system for electrified vehicles|ES2875953A1|2020-05-07|2021-11-11|Fundacion Para La Promocion De La Innovacion Investig Y Desarrollo Tecnologico En La Industria De Au|INTEGRATED BATTERY MANAGEMENT SYSTEM FOR AN ELECTRIC VEHICLE |
    DE202022100283U1|2022-01-20|2022-01-28|Vandana Ahuja|Intelligent system to automatically identify the charging voltage of electric vehicles using artificial intelligence and machine learning|
    法律状态:
    2018-08-23| FG2A| Definitive protection|Ref document number: 2640749 Country of ref document: ES Kind code of ref document: B1 Effective date: 20180823 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201630567A|ES2640749B1|2016-05-02|2016-05-02|SYSTEM OF MANAGEMENT, DIAGNOSIS AND INTERCONNECTION OF VARIOUS BATTERIES OF PROPULSION OF AN ELECTRIC VEHICLE|ES201630567A| ES2640749B1|2016-05-02|2016-05-02|SYSTEM OF MANAGEMENT, DIAGNOSIS AND INTERCONNECTION OF VARIOUS BATTERIES OF PROPULSION OF AN ELECTRIC VEHICLE|
    ARP170100703A| AR107941A1|2016-05-02|2017-03-22|SYSTEM OF MANAGEMENT, DIAGNOSIS AND INTERCONNECTION OF VARIOUS BATTERIES OF PROPULSION OF AN ELECTRIC VEHICLE|
    EP17792545.0A| EP3466742B1|2016-05-02|2017-03-24|System for managing, identifying and interconnecting a plurality of propulsion batteries of an electric vehicle|
    PCT/ES2017/070174| WO2017191339A1|2016-05-02|2017-03-24|System for managing, identifying and interconnecting a plurality of propulsion batteries of an electric vehicle|
    [返回顶部]