WO2014005470A1 - Power system of electric vehicle, electric vehicle comprising the same and method for heating battery group of electric vehicle - Google Patents

Power system of electric vehicle, electric vehicle comprising the same and method for heating battery group of electric vehicle Download PDF

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Publication number
WO2014005470A1
WO2014005470A1 PCT/CN2013/076117 CN2013076117W WO2014005470A1 WO 2014005470 A1 WO2014005470 A1 WO 2014005470A1 CN 2013076117 W CN2013076117 W CN 2013076117W WO 2014005470 A1 WO2014005470 A1 WO 2014005470A1
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WO
WIPO (PCT)
Prior art keywords
battery
battery group
heating
heater
threshold
Prior art date
Application number
PCT/CN2013/076117
Other languages
French (fr)
Inventor
Xingchi WU
Hongjun Wang
Shibin Xie
Original Assignee
Shenzhen Byd Auto R&D Company Limited
Byd Company Limited
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Shenzhen Byd Auto R&D Company Limited, Byd Company Limited filed Critical Shenzhen Byd Auto R&D Company Limited
Publication of WO2014005470A1 publication Critical patent/WO2014005470A1/en

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/60Heating or cooling; Temperature control
    • H01M10/66Heat-exchange relationships between the cells and other systems, e.g. central heating systems or fuel cells
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/60Heating or cooling; Temperature control
    • H01M10/61Types of temperature control
    • H01M10/615Heating or keeping warm
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/60Heating or cooling; Temperature control
    • H01M10/63Control systems
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/42Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
    • H01M10/44Methods for charging or discharging
    • H01M10/443Methods for charging or discharging in response to temperature
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/60Heating or cooling; Temperature control
    • H01M10/62Heating or cooling; Temperature control specially adapted for specific applications
    • H01M10/625Vehicles
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/42Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
    • H01M10/425Structural combination with electronic components, e.g. electronic circuits integrated to the outside of the casing
    • H01M2010/4271Battery management systems including electronic circuits, e.g. control of current or voltage to keep battery in healthy state, cell balancing
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/10Energy storage using batteries

Definitions

  • Exemplary embodiments of the present disclosure relate generally to a power system, and more particularly, to a power system of an electric vehicle, an electric vehicle comprising the power system and a method for heating a battery group of the electric vehicle.
  • the new energy vehicle especially the electric vehicle enters into a family as the means of transport.
  • the performance requirement especially the comfort requirement of the user for the vehicle is higher and higher, which requires that the vehicle must adapt to different running requirements. But currently most electric vehicles can not satisfy the requirements.
  • the temperature is low so that the capability of the battery, no matter the discharge capability or the battery capacity, may be decreased or even the battery can not be used.
  • the work temperature of the battery especially lithium ion battery is generally within a range from -20°C to 55°C, and the battery is not allowed to be charged at a low temperature. Under a low temperature condition, the battery in the electric vehicle may have the following problems.
  • the lithium ions may be deposited easily at the negative electrode and lose the electric activity at the low temperature, and therefore, if the battery in the electric vehicle is usually used at the low temperature, the life of the battery may be shortened and a safety problem may be caused accordingly.
  • the lithium ions When the lithium ion battery is charged at the low temperature, the lithium ions may be deposited easily at the negative electrode to become dead ions and thus the capacity of the battery may be decreased, and more ever, the deposited ions grow larger and larger during the continuous use, thus leading to a potential danger such as an internal short circuit.
  • the discharge capability of the battery is limited at the low temperature. All of the problems listed above may be not favorable for the electric vehicle which uses green and environment friendly new energy.
  • the method for heating a battery is a very important technology in the electric vehicle field.
  • a heating strategy of the battery and the performance of the battery heater influence the comfort, operation stability and safety of the vehicle directly.
  • Many new technologies are applied in the battery heating, but because of the self capability defects, the technologies are not widely applied in the vehicle field.
  • a thermal insulation sleeve is provided to warm the battery by the thermal insulation material
  • an infrared radiation film is used to heat the battery and a thermal insulation sleeve is provided to keep warm, or a heating patch is attached on the surface of the battery.
  • the methods are only suitable for the fixed battery. Furthermore, using the external power to heat the battery is not suitable for the vehicle which is not fixed in position. Therefore, the above methods have not been widely applied in the electric vehicle field.
  • a power system of an electric vehicle comprises: a battery group; a battery heater, connected with the battery group and configured to charge and discharge the battery group to heat the battery group; a battery management device, connected with the battery group and the battery heater respectively, configured to control the battery heater to heat the battery group intermittently when a temperature of the battery group is lower than a first heating threshold and a residual electric quantity of the battery group is larger than a parking electric quantity threshold, and to control the battery heater to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode; an electric distribution box, configured to distribute a voltage output by the battery group; a motor; a motor controller, connected with the motor and the electric distribution box respectively, comprising a first input terminal, a second input terminal and a pre-charging capacitor connected between the first input terminal and the second input terminal, and configured to supply power to the motor according to a control command and a voltage distributed by the electric distribution box;
  • the internal resistor of the battery itself may be heated so that the battery group may be heated. Without any external power supply, the electricity for heating is totally supplied by the battery group.
  • a heating management may be performed for the battery group by the battery management device and the battery heater, which may greatly reduce the restriction on the use of the electric vehicle at the low temperature, thus satisfying the requirements of running and charging at the low temperature.
  • the power system heats the battery group directly, and therefore, a higher heating efficiency, a lower cost and a better utility may be obtained.
  • an electric vehicle comprising the above power system.
  • the electric vehicle can normally run in a cold region and the battery group can be heated while the electric vehicle is running, thus ensuring a safe and smooth running.
  • a method for heating a battery group of an electric vehicle comprising: detecting a temperature and a residual electric quantity of the battery group; if the temperature of the battery group is lower than a first heating threshold and the residual electric quantity of the battery group is larger than a parking electric quantity threshold, controlling a battery heater to heat the battery group intermittently; controlling the battery heater to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode; and if the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is lower than the parking electric quantity threshold, indicating the battery group is inhibited from being heated or charged and the electric vehicle is inhibited from being driven.
  • the battery group may be heated directly without any external power supply, the temperature of the battery group may be increased to a required temperature and then the battery group may be charged or discharged normally, which may greatly reduce the restriction on the use of the electric vehicle at the low temperature, thus satisfying the requirements of running and charging at the low temperature. Furthermore, by sampling the throttle depth change rate of the electric vehicle and judging whether the output power of the battery group is too high, it is possible to stop heating the battery group when the output power of the battery group is too high, and thus to avoid an over discharging of the battery group, and therefore, a service life of the battery group is prolonged and a dynamic property of the electric vehicle is ensured.
  • Fig. 1 illustrates a schematic diagram of a power system of an electric vehicle according to an exemplary embodiment
  • Fig. 2 illustrates a schematic diagram of a power system of an electric vehicle according to an exemplary embodiment
  • Fig. 3 illustrates an electric principle diagram of a power system of an electric vehicle according to an exemplary embodiment
  • Fig. 4 illustrates an electric connection diagram of a power system of an electric vehicle according to an exemplary embodiment
  • Fig. 5 illustrates an electric connection diagram of a power system of an electric vehicle according to an exemplary embodiment
  • Fig. 6 illustrates a schematic diagram of an electric distribution box in a power system of an electric vehicle according to an exemplary embodiment
  • Fig. 7 illustrates a flow chart of a method for heating a battery group of an electric vehicle according to an exemplary embodiment
  • Fig. 8 illustrates a flow chart of a method for heating a battery group of an electric vehicle according to an exemplary embodiment.
  • a power system of an electric vehicle comprises: a battery group 101, a battery heater 102, a battery management device 103, an electric distribution box 104, a motor 105, a motor controller 106 and an isolation inductor L2.
  • the battery heater 102 is connected with the battery group 101 and configured to charge and discharge the battery group 101 to heat the battery group 101.
  • the battery management device 103 is connected with the battery heater 102 via a CAN cable 107 and connected with the battery group 101 via a sampling cable 108 to sample the temperature and voltage of each battery and the output current of the battery group 101.
  • the battery management device 103 is also configured to judge the current status of the electric vehicle, to calculate the temperature and the residual electric quantity of the battery group 101, and to send the control signals to the relevant electric devices via the CAN cable 107 so as to manage the relevant devices.
  • the battery management device 103 is configured to control the battery heater 102 to heat the battery group 101 intermittently when the temperature of the battery group 101 is lower than a first heating threshold and the residual electric quantity of the battery group 101 is larger than a parking electric quantity threshold, and to control the battery heater 102 to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode.
  • the electric distribution box 104 is a high voltage device for turning on and off the large current. A voltage output by the battery group 101 is distributed by the battery management device 103 by sending a control signal to the electric distribution box 104.
  • the motor controller 106 is connected with the motor 105 and the electric distribute box 104 respectively, and comprises a first input terminal, a second input terminal and a pre-charging capacitor C2 connected between the first input terminal and the second input terminal.
  • the motor controller 106 is configured to supply power to the motor 105 according to a control command and a voltage distributed to the motor controller 106 by the electric distribution box 104.
  • the motor controller 106 converts the DC supplied by the battery group 101 into the three-phase AC required by the motor 105 to supply power to the motor 105 by the internal driving circuit of the motor controller 106, and controls the motor 105 to work under a limited power according to the control signal sent by the battery management device 103.
  • the isolation inductor L2 is connected between the battery group 101 and the electric distribution box 104, and the inductance of the isolation inductor L2 matches with the capacitance of the pre-charging capacitor C2.
  • the electric vehicle when the residual electric quantity (also named as SOC (state of charge)) of the battery group 101 is larger than a running electric quantity threshold, the electric vehicle is allowed to enter in a running heating mode.
  • the running electric quantity threshold is larger than the parking electric quantity threshold.
  • the running heating mode means that besides the battery group 101 being heated by the battery heater 102, other high voltage power consumption equipments of the electric vehicle such as the motor and the air conditioner may work simultaneously under a limited power. Accordingly, the parking heating mode means that except the battery group 101 being heated by the battery heater 102, the other high voltage power consumption equipments of the electric vehicle such as the motor and the air conditioner do not work.
  • the running electric quantity threshold is a first predetermined residual electric quantity of the battery group when the electric vehicle is allowed to enter in the running heating mode
  • the parking electric quantity threshold is a second predetermined residual electric quantity of the battery when the electric vehicle is allowed to enter in the parking heating mode.
  • the battery management device 103 is further configured to adjust the output power of the battery heater 102 according to the real time temperature of the battery group 101 to heat the battery group 101 by different heating procedures.
  • the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a first power; when the temperature of the battery group 101 is higher than a fourth heating threshold and lower than a fifth heating threshold, the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a second power, in which the second power is lower than the first power; when the temperature of the battery group 101 is higher than a fifth heating threshold and lower than a sixth heating threshold, the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a third power, in which the third power is lower than the second power; and when the temperature of the battery group 101 is higher than a sixth heating threshold and lower than a seventh heating threshold, the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a fourth power, in which the fourth power is lower than the third power.
  • the third temperature threshold may be -30°C
  • the fourth temperature threshold may be -25°C
  • the fifth temperature threshold may be -20°C
  • the sixth temperature threshold may be -15°C
  • the seventh temperature threshold may be -10°C.
  • the battery management device 103 is further configured to judge whether the throttle depth change rate of the electric vehicle reaches the preset throttle depth change rate threshold, and if yes, to control the battery heater 102 to stop heating the battery group 101.
  • the throttle depth change rate is determined according to a change value of the throttle depth within a certain time.
  • a driver determines whether to control the battery heater to heat the battery group according to the change of the throttle depth within a certain time. Specifically, when the electric vehicle is in a running uphill procedure or in an urgent acceleration procedure, it needs more electric quantity, and therefore, the current throttle depth change rate of the electric vehicle will increase (the output power increases).
  • the preset threshold is the throttle depth change rate of the electric vehicle where the battery group 101 supplies the maximum power support to the electric vehicle. Therefore, once the current throttle change rate reaches the preset throttle depth change rate threshold, it normally means that the output power of the battery group 101 has reached the maximum value, in other words, the battery group 101 cannot supply power to the battery heater 102. Therefore, it is possible to avoid an over discharging of the battery group 101, ensure a safety of the battery group, and prolong the service life of the battery group.
  • the battery management device 103 is further configured to judge whether the heating time reaches a first preset time Tl and to control the battery heater 102 to suspend heating the battery group 101 when the heating time reaches the first preset time Tl. In one embodiment of the present disclosure, after controlling the battery heater 102 to suspend heating the battery group 101, the battery management device 103 is further configured to calculate a suspension time and control the battery heater 102 to heat the battery group 101 when the suspension time reaches a second preset time T2. In other words, the battery management device 103 controls the battery heater 102 to heat the battery group 101 periodically.
  • the battery group 101 is continuously heated for 45 seconds, then the heating is suspended for 15 seconds, and so on, that is, the battery group is heated intermittently. In this way, it prevents a large current from continuously surging the battery group 101, thus alleviating the influence of the large current on the battery group 101 and prolonging the service life of the battery group 101. In addition, an influence of a vortex on a power connector may be alleviated.
  • the first preset time Tl and the second preset time T2 are related to performance parameters of the battery group 101.
  • Tl/ T2 is relatively minor for the battery group 101 with better performance parameters. Otherwise, Tl/ T2 is relatively major. Therefore, Tl and T2 should be set according to practical performance parameters of the battery group 101.
  • the battery heater 102 may be configured to perform a failure self-test, for example, on an internal element of the battery heater 102, and send the test result to the battery management device 103. In this way, it prevents an error of an internal element from damaging the battery heater 102, thus improving the safety of the electric vehicle.
  • the battery heater 102 comprises: a first switch module 301, a first capacitor CI, a first inductor LI and a second switch module 302.
  • a first terminal of the first switch module 301 is connected with a first electrode of the battery group 101 and the isolation inductor L2 respectively.
  • a first terminal of the first capacitor CI is connected with a second terminal of the first switch module 301, and a second terminal of the first capacitor CI is connected with a second electrode of the battery group 101.
  • a first terminal of the first inductor LI is connected with a node between the first switch module 301 and the first capacitor CI.
  • a first terminal of the second switch module 302 is connected with a second terminal of the first inductor LI, a second terminal of the second switch module 302 is connected with the second electrode of the battery group 101.
  • the control terminal of the first switch module 301 and the control terminal of the second switch module 302 are connected with the battery management device 103.
  • the battery management device 103 sends a heating signal to the control terminal of the first switch module 301 and the control terminal of the second switch module 302 to control the first switch module 301 and the second switch module 302 to turn on in turn so as to generate a charge current and a discharge current in turn.
  • the ESR is an equivalent resistor of the battery group 101
  • the ESL is an equivalent inductor of the battery group 101
  • E is a battery package.
  • L2 is an isolation inductor and is configured to isolate the battery heating circuit Part 2 from the motor equivalent load circuit Part 5. Therefore, the reversed voltage of the battery group 101 is absorbed by the isolation inductor L2 and may not be applied to the load follow-up.
  • C2 is a pre-charging capacitor; and R is the equivalent load of the motor.
  • an internal switch module thereof turns on or off in a certain timing sequence.
  • the switch module (e.g., the first switch module 301 or the second switch module 302) may be an insulated gate bipolar transistor (IGBT).
  • IGBT1 insulated gate bipolar transistor
  • the battery package E charges the first capacitor CI by the charging loop "E-ESR-ESL-D1- Cl-E". After the battery package E has charged the first capacitor CI for a time, the voltage of the first capacitor CI is equal to the voltage of the battery package E.
  • the first capacitor CI continues being charged so that the voltage of the first capacitor CI is higher than that of the battery package.
  • the charging current is zero
  • the first capacitor CI begins to discharge by the discharging loop "C1-D1-ESL-ESR-E-C1" until the discharging current is zero.
  • the IGBT1 is off and the IGBT2 is on
  • the first capacitor CI continues discharging by the discharging loop "C1-D2-L1-IGBT2-C1". Because there is the first inductor LI, the first capacitor CI continues to discharge so that the voltage of the first capacitor CI is lower than that of the battery package E. Above process is thus repeated.
  • the isolation inductor L2 may prevent the pre- charging capacitor C2 from charging the first capacitor CI through the first switch module 301 so that the current waveform of the first capacitor CI may be controlled and thus the characteristics of the heating circuit may be controlled. Therefore, the circuit may run normally. As a result, when the motor 105 and the battery heater 102 operate simultaneously, the isolation inductor L2 may be needed.
  • the inductance L of the isolation inductor L2 may be determined according to the formula ⁇ ⁇ 2 * JLC ⁇ w h ere [ s an equivalent load work cycle of the motor 105 and C is the capacitance of the pre-charging capacitor C2.
  • the battery heater 102 needs to control the IGBT module and switch on/off the first switch module 301 or the second switch module 302. Assuming that a switching frequency of the first switch module 301 or the second switch module 302 is t, in order to reduce the influence of the battery heater 102 on the motor controller 106, it may be assumed that a cycle of a circuit comprising the isolation inductor L2 and the pre-charging capacitor C2 is T.
  • T 10t, thus meeting the design requirements. Therefore, as used herein, the expression "T is an equivalent load work cycle of the motor 105" means that T is the cycle of the circuit comprising the isolation inductor L2 and the pre-charging capacitor C2.
  • the battery heater 102 further comprises a power connector configured to connect and fasten a power cable 109.
  • the power connector needs to satisfy the requirement of the anti-vortex. When the battery heater 102 works, the frequency of the current is changed very quickly, which leads to very quick increase of the temperature of the magnetic material in the power connector, so the magnetic permeability of the power connector must be low.
  • the battery heater 102 further comprises a low voltage connector, which is connected and communicates with the external system.
  • the low voltage connector comprises a CAN cable 107 configured to connect to the battery management device 103, a self-test signal cable and a failure signal cable.
  • the isolation inductor L2 is disposed in the battery heater 102.
  • a fuse 401 is also disposed in the battery heater 102.
  • the battery heater 102 comprises the isolation inductor L2, the fuse 401 and a power supply for the battery heater 102.
  • the battery heater 102 further comprises four power connectors, in which two power connectors are connected to the battery group 101 via the power cable 109 and the other two power connectors are connected to the electric distribution box 104 via the power cable 109.
  • the power connectors are used in the head end and the tail end of a high voltage cable.
  • the battery heater 102 and the electric distribution box 104 are connected in series.
  • the isolation inductor L2 is disposed in the battery heater 102, and when the battery group 101 does not need to be heated, the battery heater 102 may be removed, so that the electric distribution box 104 may be connected directly to the battery group 101.
  • the electric vehicle does not need any battery heater in the high temperature area but needs the battery heater in the low temperature area. Therefore, if the electric vehicle needs to be modified to adapt to different areas, the modification may be small, thus greatly reducing the cost.
  • the isolation inductor L2 may be disposed in the electric distribution box 104. No matter the isolation inductor L2 is disposed in the battery heater 102 or the electric distribution box 104, the isolation inductor L2 is disposed between the battery group 101 and the electric distribution box 104. Referring to Fig. 1, the electric distribution box 104 is not connected to the battery heater 102 directly.
  • the battery group 101 comprises four power connectors, in which two power connectors are connected to the battery heater 102 via two power cables 109 and the other two power connectors are connected to the electric distribution box 104 via another two power cables 109.
  • the power system of the electric vehicle further comprises a relay 501 configured to select whether the isolation inductor L2 is connected to the circuit, as shown in Fig. 5.
  • the battery heater 102 is connected in parallel with the electric distribution box 104.
  • the fuse 401 is mounted in the battery group 101.
  • the isolation inductor L2 is disposed in the electric distribution box 104 so that the influence on the electric distribution box 104 by the battery heater 102 may be greatly reduced. Furthermore, when the battery heater 102 works, the isolation inductor L2 may be connected into the circuit by the relay 501, and when the battery heater 102 stops working, the isolation inductor L2 may be disconnected from the circuit by the relay 501.
  • the power system of the electric vehicle further comprises a cooling assembly 110 configured to cool the first switch module 301 and the second switch module 302.
  • the cooling assembly 110 comprises: a wind channel arranged in the battery heater 102; and a fan arranged at one end of the wind channel. The fan is used to dissipate heat for the battery heater 102.
  • the cooling assembly 110 comprises: a coolant channel arranged in the battery heater 102; a coolant inlet and a coolant outlet arranged in the battery heater 102 respectively.
  • the heat dissipation effect and the sealing performance of the battery heater may be improved by using the coolant to cool the battery heater.
  • the electric distribution box 104 comprises: a primary contactor 601 and a pre-contactor 602.
  • the primary contactor 601 is configured to distribute the voltage output by the battery group 101 to a power consumption equipment, such as the motor 105 of the electric vehicle.
  • the pre-contactor 602 is connected with the first input terminal 603 or the second input terminal 604 of the motor controller 106, and configured to charge the pre-charging capacitor C2 under the control of the battery management device 103 before the motor controller 106 controls the motor 105 to start.
  • the battery group may be heated. Without any external power supply, the electricity for heating is totally provided by the battery group.
  • a heating management may be performed for the battery group by the battery management device and the battery heater, which may greatly reduce the restriction on the use of the electric vehicle at the low temperature and satisfy the requirement of running and charging at the low temperature, that is, the battery group may be heated while the electric vehicle may run in the limited power.
  • the power system of the electric vehicle heats the battery group directly, and therefore, a higher heating efficiency, a lower cost and a better utility may be achieved.
  • an electric vehicle comprises the power system of the electric vehicle mentioned above.
  • the electric vehicle may run in a low temperature environment, and the electric vehicle may run while the battery group may be heated simultaneously, thus ensuring a safe and smooth running.
  • a method for heating a battery group of an electric vehicle is described in detail with reference to Fig. 7 and Fig. 8, and the detailed values (such as, -10°C) are only illustrative to explain various thresholds (such as the first heating threshold), but not used to limit the scope of the present disclosure.
  • the values of various thresholds may be changed according to actual conditions, which is obvious for a person skilled in the art.
  • the executing orders of the steps in Figs. 7-8 are only illustrative and exemplary, but not used to limit the scope of the present disclosure.
  • the executing order of the steps may be changed according to actual conditions, which is also obvious for a person skilled in the art.
  • a method for heating a battery group of an electric vehicle comprises the following steps.
  • step S701 a temperature and a residual electric quantity of the battery group are detected.
  • a battery heater is controlled to heat the battery group intermittently.
  • the battery heater is controlled to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode.
  • the battery group is inhibited from being heated or charged and the electric vehicle is inhibited from being driven.
  • the first heating threshold may be -10°C
  • the parking electric quantity threshold may be 30% of the total electric quantity of the battery group. It should be understood that the present disclosure is not limited by the above examples, in another embodiment, the first heating threshold may range from -12°C to -8°C.
  • the parking electric quantity threshold is related to a performance and a service time of the battery group. For the battery group with good performance, the parking electric quantity threshold may be a relatively lower value, such as may be lower than 30% of the total electric quantity of the battery group.
  • the method for heating the battery group of the electric vehicle may comprise the following steps.
  • step S801 the electric vehicle is powered on.
  • step S802 the temperature and the residual electric quantity of the battery group are detected.
  • step S803 it is judged whether the temperature of the battery group is lower than the first heating threshold, if yes, step S805 is followed, and if no, step S804 is followed.
  • the first heating threshold may be -10°C.
  • the battery management device controls the pre-contactor to be switched on, and after the pre-charging is finished, the primary contactor is switched on.
  • the electric vehicle runs normally.
  • step S805 the battery management device calculates whether the residual electric quantity of the battery group is larger than the running electric quantity threshold, if yes, step S808 is followed, and if no, step S806 is followed.
  • the battery management device calculates whether the residual electric quantity of the battery group is larger than the parking electric quantity threshold, if yes, step S807 is followed, and if no, step S808 is followed.
  • the running electric quantity threshold is larger than the parking electric quantity threshold.
  • the battery management device sends a message to the meter to display that the residual electric quantity of the battery group is too low so that the electric vehicle is not allowed to be heated, driven or charged.
  • step S808 the user confirms whether the battery group needs to be heated, if yes, step S810 is followed, and if no, step S809 is followed.
  • a confirmation mode may be any mode in the prior art. For example, the user presses and holds a heating button set on a control panel of the electric vehicle for a preset time (such as 2 seconds).
  • the battery management device sends a message to the meter to display that the user stops heating the battery group so that the electric vehicle is not allowed to be heated, driven or charged.
  • step S810 the battery heater performs a self-test to detect whether there is a failure, if yes, step S811 is followed, and if no, step S812 is followed.
  • the battery management device stops supplying power and sending a message to the battery heater, and sends a message to the meter to display that there is a failure in the battery heater so that the electric vehicle is not allowed to be heated, driven or charged.
  • the battery management device sends a heating signal to the battery heater to heat the battery group.
  • the battery management device controls the pre-contactor to be switched on, and after the pre-charging is finished, the primary contactor is switched on and then the battery group is heated, while the battery heater keeps on performing a self-test. Specifically, the battery management device calculates the current temperature and the current residual electric quantity of the battery group, calculates the maximum output power of the battery group according to the current temperature and the current residual electric quantity of the battery group, and controls the electric vehicle to run under a limited power according to the maximum output power.
  • the battery management device judges whether the throttle depth change rate reaches the preset throttle depth change rate threshold according to the throttle depth message, if yes, step S815 is followed, and if no, step S817 is followed.
  • the preset throttle depth change rate threshold is a current throttle depth change rate where the battery group supplies the maximum output power to the electric vehicle.
  • the battery heater stops working and the battery group only supplies power to the power consumption equipment of the electric vehicle and the driving of the electric vehicle.
  • the throttle depth change rate reaches the preset throttle depth change rate threshold when the electric vehicle is in a running uphill procedure or in an urgent acceleration procedure. Therefore, it is possible to judge whether the running uphill procedure or the urgent acceleration procedure is finished, and if yes, to control the battery heater to heat the battery group, as shown in step S816.
  • step S816 it is judged whether a running uphill procedure or an urgent acceleration procedure is finished, if yes, step S813 is followed, and if no, step S815 is followed.
  • step S817 it is judged whether the heating time reaches the first preset time, if yes, the battery heater suspends heating the battery group, and step S818 is followed, and if no, step S819 is followed.
  • step S818 the suspension time is calculated, and it is judged whether the suspension time reaches the second preset time, if yes, the battery group is heated again, that is, step S813 is followed.
  • the battery management device controls the battery heater to heat the battery group periodically. Taking a period of 1 minute as an example, the battery group is continuously heated for 45 seconds, then the heating is suspended for 15 seconds, and so on, that is, the battery group is heated intermittently. In this way, it prevents a large current from continuously surging the battery group, thus alleviating the influence of the large current on the battery group and prolonging the service life of the battery group. In addition, an influence of a vortex on a power connector may be alleviated.
  • the first preset time Tl and the second preset time T2 are related to performance parameters of the battery group 101.
  • Tl/ T2 is relatively minor for the battery group 101 with better performance parameters. Otherwise, Tl/ T2 is relatively major. Therefore, Tl and T2 should be set according to practical performance parameters of the battery group 101.
  • step S819 it is judged whether the heating button is pressed and held for a preset time, if yes, step S820 is followed, and if no, step S825 is followed.
  • the preset time may be 2 seconds.
  • step S820 it is judged whether the temperature of the battery group is higher than a running heating threshold, if yes, step S822 is followed, and if no, step S821 is followed.
  • the electric vehicle is not allowed to be heated, driven or charged.
  • step S822 it is judged whether the residual electric quantity of the battery group is larger than a second parking electric quantity threshold, if yes, step S823 is followed, and if no, step S824 is followed.
  • the second parking electric quantity threshold may be 25% of the total electric quantity of the battery group.
  • step S823 the electric vehicle is allowed to run under a limited power.
  • the battery management device sends a message to the meter to display that the user stops heating so that the electric vehicle is not allowed to be heated, driven or charged.
  • step S825 it is detected whether there is a failure in the battery heater, if yes, step S826 is followed, and if no, step S827 is followed.
  • step S826 the battery heater stops working and the meter displays an alarm.
  • step S827 it is detected whether the temperature of the battery group is higher than the first heating threshold, if yes, step S830 is followed, and if no, step S828 is followed.
  • step S828 it is detected whether the temperature of any single battery in the battery group is higher than the second heating threshold, if yes, step S830 is followed, and if no, step S829 is followed.
  • step S829 it is detected whether the total continuous heating time is higher than a heating time threshold, if yes, step S830 is followed, and if no, step S813 is followed.
  • step S830 the heating is finished and the battery heater stops working.
  • the first heating threshold may be -10°C
  • the second heating threshold may be 20°C
  • the heating time threshold may be 20 minutes.
  • the method may further comprise a step of heating the battery group with different heating powers according to different temperatures of the battery group,
  • a relatively higher heating power may cause a damage to the batter group 101 as well as result in a poor heating effect. Therefore, by applying different heating powers according to different temperature ranges, a service life of the batter group 101 may be prolonged, a heating efficiency may be improved, and a power consumption is accordingly reduced.
  • the battery management device controls the battery heater to heat the battery group with the first power; when the temperature of the battery group is higher than the fourth heating threshold and lower than the fifth heating threshold, the battery management device controls the battery heater to heat the battery group with the second power; when the temperature of the battery group is higher than the fifth heating threshold and lower than the sixth heating threshold, the battery management device controls the battery heater to heat the battery group with the third power; and when the temperature of the battery group is higher than the sixth heating threshold and lower than the seventh heating threshold, the battery management device controls the battery heater to heat the battery group with the fourth power.
  • the third temperature threshold may be -30°C
  • the fourth temperature threshold may be -25°C
  • the fifth temperature threshold may be -20°C
  • the sixth temperature threshold may be -15°C
  • the seventh temperature threshold may be -10°C.
  • the first power, the second power, the third power and the fourth power may be set according to actual conditions so as to realize that the battery group is heated efficiently and an influence on the battery group is minor.
  • the battery management device when the electric vehicle is powered on, the battery management device detects the temperature of the battery group and the status of the primary contactor.
  • the temperature of the battery group is an average of temperatures of all single batteries in the battery group.
  • the battery management device samples the temperature of each single battery in the battery group through an information collector and calculates the temperature of the battery group. If the temperature of the battery group is lower than the first heating temperature and the residual electric quantity of the battery group is larger than the parking electric quantity threshold, the user presses and holds the heating button for 2 seconds, and then the battery management device sends a message to the battery heater through the CAN cable to allow the battery group to be heated.
  • the first heating threshold may be -10°C
  • the parking electric quantity threshold may be 30% of the total electric quantity of the battery group.
  • the heating button is disposed on the meter. Provided that the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is larger than the parking electric quantity threshold, when the heating button is pressed, the battery heater is allowed to work. If the heating button is pressed again and held for 2 seconds, the battery heater is forced to stop working.
  • the primary contactor is disposed in the electric distribution box and configured to connect the motor controller to a power supply or disconnect the motor controller from a power supply.
  • the battery management device sends the control signal to the electric distribution box to control the primary contactor to be switched on so that the motor is allowed to work.
  • the motor controller converts the DC to the three-phase AC required by the motor through the driving circuit, to supply power to the motor and to allow the electric vehicle to run under a limited power.
  • the pre-contactor is also disposed in the electric distribution box and connected to the pre- charging capacitor C2 in series.
  • the pre-charging capacitor C2 is charged before the motor works.
  • the reasons may be as follows.
  • a current shock may be avoided in the pre-charging procedure and an agglomeration caused when the primary contactor is switched on may be avoided.
  • a current limiting resistor is connected in series between the pre-charging capacitor and the pre-contactor.
  • the battery management device controls the primary contactor to be switched on and then controls the pre-contactor to be switched off.
  • the voltage of the whole battery group is reduced.
  • the pre-charging capacitor C2 is charged firstly until the voltage thereof is substantially equal to that of the battery group, and then the motor is started. Because the voltage of the pre-charging capacitor can not change suddenly, by connecting the pre- charging capacitor and the motor in parallel, the affect on the voltage of the battery group resulting from the start of the motor may be decreased.
  • the battery heater When the battery heater receives the heating signal sent by the battery management device, the battery heater performs a self-test to detect whether there is a failure in the battery heater. In one embodiment of the present disclosure, the battery heater sends a single pulse of 0.5ms to detect whether there is a failure in the battery heater. If there is not any failure, the battery heater sends a control pulse (for example with a cycle of 20ms and a duty ratio of 20%) to the internal switch module to make the battery group short the circuit in a short time. So the heating purpose is achieved. Meanwhile, the battery heater sends a CAN signal to the meter. The meter receives the CAN signal and displays that "the battery group is being heated".
  • a control pulse for example with a cycle of 20ms and a duty ratio of 20%
  • the battery management device and the battery heater keep on detecting the status of the battery group. If the temperature of the battery group is higher than the first heating threshold, or the continuous heating time is larger than the heating time threshold, or the maximum temperature of a single battery in the battery group is higher than the second heating threshold, the battery heater stops sending the control pulse to the internal switch module to stop heating the battery group.
  • the battery heater sends a CAN signal to the meter.
  • the meter receives the CAN signal and displays that "the heating is finished”.
  • the heating procedure is finished.
  • the second heating threshold may be 20°C
  • the heating time threshold may the 20 minutes.
  • the battery group is stopped from being heated.
  • the battery management device works normally. If the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is less than the parking electric quantity threshold, the primary contactor is not switched on and the battery management device sends the CAN signal to the battery heater and the meter, so that the battery group is not allowed to be heated. When the meter receives the CAN signal, the meter displays that "the residual electric quantity of the battery group is not enough" so that the electric vehicle is not allowed to be heated, driven or charged.
  • a failure of the battery heater including under voltage protection, over- voltage protection, overheat protection, pulse width interval protection or maximum turn-on time protection, appears during the self-test process, it is not allowed to heat the battery group.
  • the battery heater sends a failure signal.
  • the meter receives the failure signal and displays that "a failure in the battery heater". The heating is not allowed.
  • the battery heater stops heating the battery group and sends a failure signal.
  • the meter receives the failure signal and displays that "a failure in the battery heater". The heating is ceased.
  • the battery heater comprises a protection circuit to prevent the failures mentioned above.
  • the protection circuit will be described in detail as follows.
  • the PWM (pulse width modulation) wave should be maintained at a high level for 2 seconds, and then the failure signal is reset and the protection circuit is recovered to a normal status. If the failure signal can not be reset by the PWM wave in 2 seconds, a permanent error occurs in the protection circuit so that the protection circuit can not work normally.
  • the frequency of the pulse sent by a DSP may not be too high and the pulse width may not be too long.
  • the maximum pulse width may be 5ms and the minimum interval may be 7-10 ms, or else a failure signal will be output.
  • a DC-DC isolation power supply is used to drive the IGBT.
  • the positive bias voltage for the gate terminal of the IGBT may be +15V, and the negative bias voltage for the gate terminal of the IGBT may be -7V.
  • the negative bias voltage for the gate terminal of IGBT may turn off the IGBT quickly and avoid a malfunction of turning on IGBT because of the overlarge surge current.
  • the protection circuit comprises an under voltage protection circuit.
  • the under voltage protection circuit may avoid an increase of the power consumption of the IGBT caused by the deficient driving voltage.
  • the driving voltage decreases to a first voltage threshold, the under voltage protection circuit starts to work.
  • the first voltage threshold may be 9V.
  • the over-heat protection circuit may avoid the damage to the IGBT caused by the high temperature.
  • the protection circuit samples the temperature by using a thermistor. When the temperature of the IGBT is higher than a safe temperature threshold, the over-heat protection circuit starts to work.
  • the protection circuit may also be configured to detect whether there is an open circuit in the thermistor. When there is an open circuit in the thermistor, the equivalent impedance is infinite and a protection signal is output.
  • the safe temperature threshold may be 85°C.
  • the over-voltage protection circuit may avoid the over high voltage of the collector terminal to damage the IGBT at the moment of turning off the IGBT.
  • a protection signal will be output.
  • the second voltage threshold may be 800V.
  • the battery heater stops heating the battery group so that the battery group is not allowed to be charged and the electric vehicle is not allowed to be driven.
  • the battery group of the electric vehicle may be heated without any external power supply.
  • the battery group is heated to a required temperature and then may be charged or discharged normally. So the restriction on the use of the electric vehicle at the low temperature may be greatly reduced and the requirements of running and charging at the low temperature may be satisfied.
  • by heating the battery group with different heating powers according to the real-time temperature of the battery group a service life of the battery group is prolonged and a power consumption is reduced.

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Abstract

A power system of an electric vehicle, an electric vehicle comprising the same and a method for heating a battery group of the electric vehicle are provided. The power system comprises: a battery group; a battery heater connected with the battery group; a battery management device connected with the battery group and the battery heater respectively, configured to control the battery heater to heat the battery group intermittently when a temperature of the battery group is lower than a first heating threshold and a residual electric quantity of the battery group is larger than a parking electric quantity threshold and to control the battery heater to stop heating the battery group according to a current throttle depth change rate when the battery group is in a running heating mode; an electric distribution box; a motor controller connected with a motor and the electric distribution box respectively; and an isolation inductor.

Description

POWER SYSTEM OF ELECTRIC VEHICLE, ELECTRIC VEHICLE COMPRISING THE SAME AND METHOD FOR HEATING BATTERY GROUP OF ELECTRIC
VEHICLE CROSS-REFERENCE TO RELATED APPLICATION
This application claims priority to, and benefits of Chinese Patent Application Serial No. 201210160619.X, filed with the State Intellectual Property Office of P. R. C. on May 22, 2012, the entire contents of which are incorporated herein by reference. FIELD
Exemplary embodiments of the present disclosure relate generally to a power system, and more particularly, to a power system of an electric vehicle, an electric vehicle comprising the power system and a method for heating a battery group of the electric vehicle. BACKGROUND
With the development of the science technology, the new energy vehicle especially the electric vehicle enters into a family as the means of transport. The performance requirement especially the comfort requirement of the user for the vehicle is higher and higher, which requires that the vehicle must adapt to different running requirements. But currently most electric vehicles can not satisfy the requirements. Especially in winter, the temperature is low so that the capability of the battery, no matter the discharge capability or the battery capacity, may be decreased or even the battery can not be used. Specifically, the work temperature of the battery especially lithium ion battery is generally within a range from -20°C to 55°C, and the battery is not allowed to be charged at a low temperature. Under a low temperature condition, the battery in the electric vehicle may have the following problems. (1) The lithium ions may be deposited easily at the negative electrode and lose the electric activity at the low temperature, and therefore, if the battery in the electric vehicle is usually used at the low temperature, the life of the battery may be shortened and a safety problem may be caused accordingly. (2) When the lithium ion battery is charged at the low temperature, the lithium ions may be deposited easily at the negative electrode to become dead ions and thus the capacity of the battery may be decreased, and more ever, the deposited ions grow larger and larger during the continuous use, thus leading to a potential danger such as an internal short circuit. (3) The discharge capability of the battery is limited at the low temperature. All of the problems listed above may be not favorable for the electric vehicle which uses green and environment friendly new energy.
The method for heating a battery is a very important technology in the electric vehicle field. A heating strategy of the battery and the performance of the battery heater influence the comfort, operation stability and safety of the vehicle directly. Many new technologies are applied in the battery heating, but because of the self capability defects, the technologies are not widely applied in the vehicle field. For example, a thermal insulation sleeve is provided to warm the battery by the thermal insulation material, an infrared radiation film is used to heat the battery and a thermal insulation sleeve is provided to keep warm, or a heating patch is attached on the surface of the battery. The methods are only suitable for the fixed battery. Furthermore, using the external power to heat the battery is not suitable for the vehicle which is not fixed in position. Therefore, the above methods have not been widely applied in the electric vehicle field. SUMMARY
According to a first aspect of the present disclosure, a power system of an electric vehicle is provided. The power system comprises: a battery group; a battery heater, connected with the battery group and configured to charge and discharge the battery group to heat the battery group; a battery management device, connected with the battery group and the battery heater respectively, configured to control the battery heater to heat the battery group intermittently when a temperature of the battery group is lower than a first heating threshold and a residual electric quantity of the battery group is larger than a parking electric quantity threshold, and to control the battery heater to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode; an electric distribution box, configured to distribute a voltage output by the battery group; a motor; a motor controller, connected with the motor and the electric distribution box respectively, comprising a first input terminal, a second input terminal and a pre-charging capacitor connected between the first input terminal and the second input terminal, and configured to supply power to the motor according to a control command and a voltage distributed by the electric distribution box; and an isolation inductor, connected between the battery group and the electric distribution box, in which an inductance of the isolation inductor matches with a capacitance of the pre-charging capacitor. With the power system of the electric vehicle according to embodiments of the present disclosure, by using a large current discharge of the battery group in the electric vehicle, the internal resistor of the battery itself may be heated so that the battery group may be heated. Without any external power supply, the electricity for heating is totally supplied by the battery group. A heating management may be performed for the battery group by the battery management device and the battery heater, which may greatly reduce the restriction on the use of the electric vehicle at the low temperature, thus satisfying the requirements of running and charging at the low temperature. Moreover, the power system heats the battery group directly, and therefore, a higher heating efficiency, a lower cost and a better utility may be obtained. Furthermore, by sampling the throttle depth change rate of the electric vehicle and judging whether the output power of the battery group is too high, it is possible to stop heating the battery group when the output power of the battery group is too high, and thus to avoid an over discharging of the battery group, and therefore, a service life of the battery group is prolonged and a dynamic property of the electric vehicle is ensured. In addition, by heating the battery intermittently (i.e., heating continuously the battery group for a time and then suspending heating for a time, and repeating the above process), an influence of a large current on the battery group is alleviated, and thus the service life of the battery group is prolonged.
According to a second aspect of the present disclosure, an electric vehicle comprising the above power system is provided. The electric vehicle can normally run in a cold region and the battery group can be heated while the electric vehicle is running, thus ensuring a safe and smooth running.
According to a third aspect of the present disclosure, a method for heating a battery group of an electric vehicle is provided, comprising: detecting a temperature and a residual electric quantity of the battery group; if the temperature of the battery group is lower than a first heating threshold and the residual electric quantity of the battery group is larger than a parking electric quantity threshold, controlling a battery heater to heat the battery group intermittently; controlling the battery heater to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode; and if the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is lower than the parking electric quantity threshold, indicating the battery group is inhibited from being heated or charged and the electric vehicle is inhibited from being driven. With the method for heating the battery group of the electric vehicle according to embodiments of the present disclosure, the battery group may be heated directly without any external power supply, the temperature of the battery group may be increased to a required temperature and then the battery group may be charged or discharged normally, which may greatly reduce the restriction on the use of the electric vehicle at the low temperature, thus satisfying the requirements of running and charging at the low temperature. Furthermore, by sampling the throttle depth change rate of the electric vehicle and judging whether the output power of the battery group is too high, it is possible to stop heating the battery group when the output power of the battery group is too high, and thus to avoid an over discharging of the battery group, and therefore, a service life of the battery group is prolonged and a dynamic property of the electric vehicle is ensured. In addition, by heating the battery intermittently (i.e., heating continuously for a time and then suspend heating for a time, and repeating the above process), an influence of a large current on the battery group is alleviated, and thus the service life of the battery group is prolonged. BRIEF DESCRIPTION OF THE DRAWINGS
Having thus described exemplary embodiments of the present disclosure in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale.
Fig. 1 illustrates a schematic diagram of a power system of an electric vehicle according to an exemplary embodiment;
Fig. 2 illustrates a schematic diagram of a power system of an electric vehicle according to an exemplary embodiment;
Fig. 3 illustrates an electric principle diagram of a power system of an electric vehicle according to an exemplary embodiment;
Fig. 4 illustrates an electric connection diagram of a power system of an electric vehicle according to an exemplary embodiment;
Fig. 5 illustrates an electric connection diagram of a power system of an electric vehicle according to an exemplary embodiment;
Fig. 6 illustrates a schematic diagram of an electric distribution box in a power system of an electric vehicle according to an exemplary embodiment;
Fig. 7 illustrates a flow chart of a method for heating a battery group of an electric vehicle according to an exemplary embodiment; and
Fig. 8 illustrates a flow chart of a method for heating a battery group of an electric vehicle according to an exemplary embodiment. DETAILED DESCRIPTION
Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. It is readily appreciated by those having ordinary skill in the art that the presently claimed subject matter may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.
In the description, relative terms such as "longitudinal", "lateral", "lower", "upper", "front",
"rear", "left", "right", "horizontal", "vertical", "above", "below", "up", "top", "bottom" "external", "internal " as well as derivative thereof (e.g., "horizontally", "downwardly", "upwardly", etc.) should be construed to refer to the orientation as then described or as shown in the drawings under discussion. These relative terms are for convenience of description and do not require that the present disclosure be constructed or operated in a particular orientation.
In the description, terms concerning attachments, coupling and the like, such as "connected" and "interconnected", refer to a relationship in which structures are secured or attached to one another through mechanical or electrical connection, or directly or indirectly through intervening structures, unless expressly described otherwise. Specific implications of the above phraseology and terminology may be understood by those skilled in the art according to specific situations.
Referring to Fig. 1 and Fig. 2, in some embodiments of the present disclosure, a power system of an electric vehicle comprises: a battery group 101, a battery heater 102, a battery management device 103, an electric distribution box 104, a motor 105, a motor controller 106 and an isolation inductor L2.
The battery heater 102 is connected with the battery group 101 and configured to charge and discharge the battery group 101 to heat the battery group 101. The battery management device 103 is connected with the battery heater 102 via a CAN cable 107 and connected with the battery group 101 via a sampling cable 108 to sample the temperature and voltage of each battery and the output current of the battery group 101. In addition, the battery management device 103 is also configured to judge the current status of the electric vehicle, to calculate the temperature and the residual electric quantity of the battery group 101, and to send the control signals to the relevant electric devices via the CAN cable 107 so as to manage the relevant devices. Specifically, the battery management device 103 is configured to control the battery heater 102 to heat the battery group 101 intermittently when the temperature of the battery group 101 is lower than a first heating threshold and the residual electric quantity of the battery group 101 is larger than a parking electric quantity threshold, and to control the battery heater 102 to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode. The electric distribution box 104 is a high voltage device for turning on and off the large current. A voltage output by the battery group 101 is distributed by the battery management device 103 by sending a control signal to the electric distribution box 104. The motor controller 106 is connected with the motor 105 and the electric distribute box 104 respectively, and comprises a first input terminal, a second input terminal and a pre-charging capacitor C2 connected between the first input terminal and the second input terminal. The motor controller 106 is configured to supply power to the motor 105 according to a control command and a voltage distributed to the motor controller 106 by the electric distribution box 104. Specifically, the motor controller 106 converts the DC supplied by the battery group 101 into the three-phase AC required by the motor 105 to supply power to the motor 105 by the internal driving circuit of the motor controller 106, and controls the motor 105 to work under a limited power according to the control signal sent by the battery management device 103. The isolation inductor L2 is connected between the battery group 101 and the electric distribution box 104, and the inductance of the isolation inductor L2 matches with the capacitance of the pre-charging capacitor C2.
In one embodiment of the present disclosure, when the residual electric quantity (also named as SOC (state of charge)) of the battery group 101 is larger than a running electric quantity threshold, the electric vehicle is allowed to enter in a running heating mode. The running electric quantity threshold is larger than the parking electric quantity threshold.
The running heating mode means that besides the battery group 101 being heated by the battery heater 102, other high voltage power consumption equipments of the electric vehicle such as the motor and the air conditioner may work simultaneously under a limited power. Accordingly, the parking heating mode means that except the battery group 101 being heated by the battery heater 102, the other high voltage power consumption equipments of the electric vehicle such as the motor and the air conditioner do not work. The running electric quantity threshold is a first predetermined residual electric quantity of the battery group when the electric vehicle is allowed to enter in the running heating mode, and the parking electric quantity threshold is a second predetermined residual electric quantity of the battery when the electric vehicle is allowed to enter in the parking heating mode.
In general, if the temperature of the batter group 101 is relatively lower, a relatively higher heating power may cause a damage to the batter group 101 as well as result in a poor heating effect. Therefore, by applying different heating powers according to different temperature ranges, a service life of the batter group 101 may be prolonged, a heating efficiency may be improved, and a power consumption may be accordingly reduced. Therefore, in one embodiment of the present disclosure, the battery management device 103 is further configured to adjust the output power of the battery heater 102 according to the real time temperature of the battery group 101 to heat the battery group 101 by different heating procedures. Specifically, when the temperature of the battery group 101 is higher than a third heating threshold and lower than a fourth heating threshold, the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a first power; when the temperature of the battery group 101 is higher than a fourth heating threshold and lower than a fifth heating threshold, the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a second power, in which the second power is lower than the first power; when the temperature of the battery group 101 is higher than a fifth heating threshold and lower than a sixth heating threshold, the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a third power, in which the third power is lower than the second power; and when the temperature of the battery group 101 is higher than a sixth heating threshold and lower than a seventh heating threshold, the battery management device 103 controls the battery heater 102 to heat the battery group 101 with a fourth power, in which the fourth power is lower than the third power. In one embodiment of the present disclosure, the third temperature threshold may be -30°C, the fourth temperature threshold may be -25°C, the fifth temperature threshold may be -20°C, the sixth temperature threshold may be -15°C, and the seventh temperature threshold may be -10°C.
In another embodiment of the present disclosure, the battery management device 103 is further configured to judge whether the throttle depth change rate of the electric vehicle reaches the preset throttle depth change rate threshold, and if yes, to control the battery heater 102 to stop heating the battery group 101. It should be understood that the throttle depth change rate is determined according to a change value of the throttle depth within a certain time. In other words, a driver determines whether to control the battery heater to heat the battery group according to the change of the throttle depth within a certain time. Specifically, when the electric vehicle is in a running uphill procedure or in an urgent acceleration procedure, it needs more electric quantity, and therefore, the current throttle depth change rate of the electric vehicle will increase (the output power increases). Furthermore, there is a limit (preset threshold) for the output power of the battery group 101, the preset threshold is the throttle depth change rate of the electric vehicle where the battery group 101 supplies the maximum power support to the electric vehicle. Therefore, once the current throttle change rate reaches the preset throttle depth change rate threshold, it normally means that the output power of the battery group 101 has reached the maximum value, in other words, the battery group 101 cannot supply power to the battery heater 102. Therefore, it is possible to avoid an over discharging of the battery group 101, ensure a safety of the battery group, and prolong the service life of the battery group.
In one embodiment of the present disclosure, the battery management device 103 is further configured to judge whether the heating time reaches a first preset time Tl and to control the battery heater 102 to suspend heating the battery group 101 when the heating time reaches the first preset time Tl. In one embodiment of the present disclosure, after controlling the battery heater 102 to suspend heating the battery group 101, the battery management device 103 is further configured to calculate a suspension time and control the battery heater 102 to heat the battery group 101 when the suspension time reaches a second preset time T2. In other words, the battery management device 103 controls the battery heater 102 to heat the battery group 101 periodically. Taking a period of 1 minute as an example, the battery group 101 is continuously heated for 45 seconds, then the heating is suspended for 15 seconds, and so on, that is, the battery group is heated intermittently. In this way, it prevents a large current from continuously surging the battery group 101, thus alleviating the influence of the large current on the battery group 101 and prolonging the service life of the battery group 101. In addition, an influence of a vortex on a power connector may be alleviated.
It should be noted that, the first preset time Tl and the second preset time T2 are related to performance parameters of the battery group 101. Tl/ T2 is relatively minor for the battery group 101 with better performance parameters. Otherwise, Tl/ T2 is relatively major. Therefore, Tl and T2 should be set according to practical performance parameters of the battery group 101.
In one embodiment of the present disclosure, the battery heater 102 may be configured to perform a failure self-test, for example, on an internal element of the battery heater 102, and send the test result to the battery management device 103. In this way, it prevents an error of an internal element from damaging the battery heater 102, thus improving the safety of the electric vehicle.
Referring to Fig. 3, the battery heater 102 comprises: a first switch module 301, a first capacitor CI, a first inductor LI and a second switch module 302. A first terminal of the first switch module 301 is connected with a first electrode of the battery group 101 and the isolation inductor L2 respectively. A first terminal of the first capacitor CI is connected with a second terminal of the first switch module 301, and a second terminal of the first capacitor CI is connected with a second electrode of the battery group 101. A first terminal of the first inductor LI is connected with a node between the first switch module 301 and the first capacitor CI. A first terminal of the second switch module 302 is connected with a second terminal of the first inductor LI, a second terminal of the second switch module 302 is connected with the second electrode of the battery group 101. The control terminal of the first switch module 301 and the control terminal of the second switch module 302 are connected with the battery management device 103. The battery management device 103 sends a heating signal to the control terminal of the first switch module 301 and the control terminal of the second switch module 302 to control the first switch module 301 and the second switch module 302 to turn on in turn so as to generate a charge current and a discharge current in turn. When the first switch module 301 is on, the second switch module 302 is off, and when the second switch module 302 is on, the first switch module 301 is off.
Referring to Fig. 3, the ESR is an equivalent resistor of the battery group 101, the ESL is an equivalent inductor of the battery group 101, and E is a battery package. L2 is an isolation inductor and is configured to isolate the battery heating circuit Part 2 from the motor equivalent load circuit Part 5. Therefore, the reversed voltage of the battery group 101 is absorbed by the isolation inductor L2 and may not be applied to the load follow-up. C2 is a pre-charging capacitor; and R is the equivalent load of the motor. When the battery heater works, an internal switch module thereof turns on or off in a certain timing sequence.
Referring to Fig. 3, according to one embodiment of the present disclosure, the switch module (e.g., the first switch module 301 or the second switch module 302) may be an insulated gate bipolar transistor (IGBT). When the battery heater starts to work, the internal elements of the battery heater such as inductor, capacitor are in an initial status and do not store any energy. The work procedure of the battery heater will be described below. When an IGBT1 is on and an IGBT2 is off, the battery package E charges the first capacitor CI by the charging loop "E-ESR-ESL-D1- Cl-E". After the battery package E has charged the first capacitor CI for a time, the voltage of the first capacitor CI is equal to the voltage of the battery package E. But because there is an inductive element in the battery heater, the first capacitor CI continues being charged so that the voltage of the first capacitor CI is higher than that of the battery package. When the charging current is zero, the first capacitor CI begins to discharge by the discharging loop "C1-D1-ESL-ESR-E-C1" until the discharging current is zero. When the IGBT1 is off and the IGBT2 is on, the first capacitor CI continues discharging by the discharging loop "C1-D2-L1-IGBT2-C1". Because there is the first inductor LI, the first capacitor CI continues to discharge so that the voltage of the first capacitor CI is lower than that of the battery package E. Above process is thus repeated.
In one embodiment of the present disclosure , the isolation inductor L2 may prevent the pre- charging capacitor C2 from charging the first capacitor CI through the first switch module 301 so that the current waveform of the first capacitor CI may be controlled and thus the characteristics of the heating circuit may be controlled. Therefore, the circuit may run normally. As a result, when the motor 105 and the battery heater 102 operate simultaneously, the isolation inductor L2 may be needed.
In one embodiment of the present disclosure, the inductance L of the isolation inductor L2 may be determined according to the formula ^ ~ 2 *JLC ^ where [s an equivalent load work cycle of the motor 105 and C is the capacitance of the pre-charging capacitor C2. The battery heater 102 needs to control the IGBT module and switch on/off the first switch module 301 or the second switch module 302. Assuming that a switching frequency of the first switch module 301 or the second switch module 302 is t, in order to reduce the influence of the battery heater 102 on the motor controller 106, it may be assumed that a cycle of a circuit comprising the isolation inductor L2 and the pre-charging capacitor C2 is T. In one embodiment, T >10t, thus meeting the design requirements. Therefore, as used herein, the expression "T is an equivalent load work cycle of the motor 105" means that T is the cycle of the circuit comprising the isolation inductor L2 and the pre-charging capacitor C2.
In one embodiment of the present disclosure, the battery heater 102 further comprises a power connector configured to connect and fasten a power cable 109. The power connector needs to satisfy the requirement of the anti-vortex. When the battery heater 102 works, the frequency of the current is changed very quickly, which leads to very quick increase of the temperature of the magnetic material in the power connector, so the magnetic permeability of the power connector must be low. In one embodiment of the present disclosure, the battery heater 102 further comprises a low voltage connector, which is connected and communicates with the external system. The low voltage connector comprises a CAN cable 107 configured to connect to the battery management device 103, a self-test signal cable and a failure signal cable.
Referring to Fig. 2 and Fig. 4, in one embodiment of the present disclosure, the isolation inductor L2 is disposed in the battery heater 102. A fuse 401 is also disposed in the battery heater 102. As shown in Fig. 4, the battery heater 102 comprises the isolation inductor L2, the fuse 401 and a power supply for the battery heater 102. The battery heater 102 further comprises four power connectors, in which two power connectors are connected to the battery group 101 via the power cable 109 and the other two power connectors are connected to the electric distribution box 104 via the power cable 109. In one embodiment of the present disclosure, the power connectors are used in the head end and the tail end of a high voltage cable. The battery heater 102 and the electric distribution box 104 are connected in series.
In one embodiment of the present disclosure, the isolation inductor L2 is disposed in the battery heater 102, and when the battery group 101 does not need to be heated, the battery heater 102 may be removed, so that the electric distribution box 104 may be connected directly to the battery group 101. The electric vehicle does not need any battery heater in the high temperature area but needs the battery heater in the low temperature area. Therefore, if the electric vehicle needs to be modified to adapt to different areas, the modification may be small, thus greatly reducing the cost.
Referring to Fig. 1 and Fig. 5, in one embodiment of the present disclosure, the isolation inductor L2 may be disposed in the electric distribution box 104. No matter the isolation inductor L2 is disposed in the battery heater 102 or the electric distribution box 104, the isolation inductor L2 is disposed between the battery group 101 and the electric distribution box 104. Referring to Fig. 1, the electric distribution box 104 is not connected to the battery heater 102 directly. The battery group 101 comprises four power connectors, in which two power connectors are connected to the battery heater 102 via two power cables 109 and the other two power connectors are connected to the electric distribution box 104 via another two power cables 109. In this embodiment, the power system of the electric vehicle further comprises a relay 501 configured to select whether the isolation inductor L2 is connected to the circuit, as shown in Fig. 5. The battery heater 102 is connected in parallel with the electric distribution box 104. The fuse 401 is mounted in the battery group 101.
The isolation inductor L2 is disposed in the electric distribution box 104 so that the influence on the electric distribution box 104 by the battery heater 102 may be greatly reduced. Furthermore, when the battery heater 102 works, the isolation inductor L2 may be connected into the circuit by the relay 501, and when the battery heater 102 stops working, the isolation inductor L2 may be disconnected from the circuit by the relay 501.
In one embodiment of the present disclosure, as shown in Figs. 1-3, the power system of the electric vehicle further comprises a cooling assembly 110 configured to cool the first switch module 301 and the second switch module 302.
In one embodiment of the present disclosure, the cooling assembly 110 comprises: a wind channel arranged in the battery heater 102; and a fan arranged at one end of the wind channel. The fan is used to dissipate heat for the battery heater 102.
In another embodiment of the present disclosure, the cooling assembly 110 comprises: a coolant channel arranged in the battery heater 102; a coolant inlet and a coolant outlet arranged in the battery heater 102 respectively. The heat dissipation effect and the sealing performance of the battery heater may be improved by using the coolant to cool the battery heater.
Referring to Fig. 6, the electric distribution box 104 comprises: a primary contactor 601 and a pre-contactor 602. The primary contactor 601 is configured to distribute the voltage output by the battery group 101 to a power consumption equipment, such as the motor 105 of the electric vehicle. The pre-contactor 602 is connected with the first input terminal 603 or the second input terminal 604 of the motor controller 106, and configured to charge the pre-charging capacitor C2 under the control of the battery management device 103 before the motor controller 106 controls the motor 105 to start.
With the power system of the electric vehicle of the present disclosure, by using the battery group to discharge with large current and by the heating of the internal resistor of the battery group, the battery group may be heated. Without any external power supply, the electricity for heating is totally provided by the battery group. A heating management may be performed for the battery group by the battery management device and the battery heater, which may greatly reduce the restriction on the use of the electric vehicle at the low temperature and satisfy the requirement of running and charging at the low temperature, that is, the battery group may be heated while the electric vehicle may run in the limited power. Moreover, the power system of the electric vehicle heats the battery group directly, and therefore, a higher heating efficiency, a lower cost and a better utility may be achieved. Furthermore, by sampling the throttle depth change rate of the electric vehicle and judging whether the output power of the battery group is too high, it is possible to stop heating the battery group when the output power of the battery group is too high, and thus to avoid an over discharging of the battery group, and therefore, a service life of the battery group is prolonged and a dynamic property of the electric vehicle is ensured. In addition, by heating the battery intermittently (i.e., heating continuously the battery group for a time and then suspend heating for a time, and so on), an influence of a large current on the battery group is alleviated, and thus the service life of the battery group is prolonged.
In one embodiment of the present disclosure, an electric vehicle is provided. The electric vehicle comprises the power system of the electric vehicle mentioned above. The electric vehicle may run in a low temperature environment, and the electric vehicle may run while the battery group may be heated simultaneously, thus ensuring a safe and smooth running.
In the following, a method for heating a battery group of an electric vehicle is described in detail with reference to Fig. 7 and Fig. 8, and the detailed values (such as, -10°C) are only illustrative to explain various thresholds (such as the first heating threshold), but not used to limit the scope of the present disclosure. The values of various thresholds may be changed according to actual conditions, which is obvious for a person skilled in the art. Furthermore, the executing orders of the steps in Figs. 7-8 are only illustrative and exemplary, but not used to limit the scope of the present disclosure. The executing order of the steps may be changed according to actual conditions, which is also obvious for a person skilled in the art.
Referring to Fig. 7, a method for heating a battery group of an electric vehicle is provided. The method comprises the following steps.
At step S701, a temperature and a residual electric quantity of the battery group are detected.
At step S702, if the temperature of the battery group is lower than a first heating threshold and the residual electric quantity of the battery group is larger than a parking electric quantity threshold, a battery heater is controlled to heat the battery group intermittently.
At step S703, the battery heater is controlled to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode. At step S704, if the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is lower than the parking electric quantity threshold, the battery group is inhibited from being heated or charged and the electric vehicle is inhibited from being driven.
In this embodiment, the first heating threshold may be -10°C, the parking electric quantity threshold may be 30% of the total electric quantity of the battery group. It should be understood that the present disclosure is not limited by the above examples, in another embodiment, the first heating threshold may range from -12°C to -8°C. The parking electric quantity threshold is related to a performance and a service time of the battery group. For the battery group with good performance, the parking electric quantity threshold may be a relatively lower value, such as may be lower than 30% of the total electric quantity of the battery group.
According to an embodiment of the present disclosure, referring to Fig. 8, the method for heating the battery group of the electric vehicle may comprise the following steps.
At step S801, the electric vehicle is powered on.
At step S802, the temperature and the residual electric quantity of the battery group are detected.
At step S803, it is judged whether the temperature of the battery group is lower than the first heating threshold, if yes, step S805 is followed, and if no, step S804 is followed. In one embodiment, the first heating threshold may be -10°C.
At step S804, the battery management device controls the pre-contactor to be switched on, and after the pre-charging is finished, the primary contactor is switched on. The electric vehicle runs normally.
At step S805, the battery management device calculates whether the residual electric quantity of the battery group is larger than the running electric quantity threshold, if yes, step S808 is followed, and if no, step S806 is followed.
At step S806, the battery management device calculates whether the residual electric quantity of the battery group is larger than the parking electric quantity threshold, if yes, step S807 is followed, and if no, step S808 is followed. The running electric quantity threshold is larger than the parking electric quantity threshold.
At step S807, the battery management device sends a message to the meter to display that the residual electric quantity of the battery group is too low so that the electric vehicle is not allowed to be heated, driven or charged.
At step S808, the user confirms whether the battery group needs to be heated, if yes, step S810 is followed, and if no, step S809 is followed. A confirmation mode may be any mode in the prior art. For example, the user presses and holds a heating button set on a control panel of the electric vehicle for a preset time (such as 2 seconds).
At step S809, the battery management device sends a message to the meter to display that the user stops heating the battery group so that the electric vehicle is not allowed to be heated, driven or charged.
At step S810, the battery heater performs a self-test to detect whether there is a failure, if yes, step S811 is followed, and if no, step S812 is followed.
At step S811, the battery management device stops supplying power and sending a message to the battery heater, and sends a message to the meter to display that there is a failure in the battery heater so that the electric vehicle is not allowed to be heated, driven or charged.
At step S812, the battery management device sends a heating signal to the battery heater to heat the battery group.
At step S813, the battery management device controls the pre-contactor to be switched on, and after the pre-charging is finished, the primary contactor is switched on and then the battery group is heated, while the battery heater keeps on performing a self-test. Specifically, the battery management device calculates the current temperature and the current residual electric quantity of the battery group, calculates the maximum output power of the battery group according to the current temperature and the current residual electric quantity of the battery group, and controls the electric vehicle to run under a limited power according to the maximum output power.
At step S814, the battery management device judges whether the throttle depth change rate reaches the preset throttle depth change rate threshold according to the throttle depth message, if yes, step S815 is followed, and if no, step S817 is followed. The preset throttle depth change rate threshold is a current throttle depth change rate where the battery group supplies the maximum output power to the electric vehicle.
At step S815, the battery heater stops working and the battery group only supplies power to the power consumption equipment of the electric vehicle and the driving of the electric vehicle. In general, the throttle depth change rate reaches the preset throttle depth change rate threshold when the electric vehicle is in a running uphill procedure or in an urgent acceleration procedure. Therefore, it is possible to judge whether the running uphill procedure or the urgent acceleration procedure is finished, and if yes, to control the battery heater to heat the battery group, as shown in step S816.
At step S816, it is judged whether a running uphill procedure or an urgent acceleration procedure is finished, if yes, step S813 is followed, and if no, step S815 is followed.
At step S817, it is judged whether the heating time reaches the first preset time, if yes, the battery heater suspends heating the battery group, and step S818 is followed, and if no, step S819 is followed.
At step S818, the suspension time is calculated, and it is judged whether the suspension time reaches the second preset time, if yes, the battery group is heated again, that is, step S813 is followed.
At step S817 and step S818, the battery management device controls the battery heater to heat the battery group periodically. Taking a period of 1 minute as an example, the battery group is continuously heated for 45 seconds, then the heating is suspended for 15 seconds, and so on, that is, the battery group is heated intermittently. In this way, it prevents a large current from continuously surging the battery group, thus alleviating the influence of the large current on the battery group and prolonging the service life of the battery group. In addition, an influence of a vortex on a power connector may be alleviated.
It should be noted that, the first preset time Tl and the second preset time T2 are related to performance parameters of the battery group 101. Tl/ T2 is relatively minor for the battery group 101 with better performance parameters. Otherwise, Tl/ T2 is relatively major. Therefore, Tl and T2 should be set according to practical performance parameters of the battery group 101.
At step S819, it is judged whether the heating button is pressed and held for a preset time, if yes, step S820 is followed, and if no, step S825 is followed. In one embodiment, the preset time may be 2 seconds.
At step S820, it is judged whether the temperature of the battery group is higher than a running heating threshold, if yes, step S822 is followed, and if no, step S821 is followed.
At step S821, the electric vehicle is not allowed to be heated, driven or charged.
At step S822, it is judged whether the residual electric quantity of the battery group is larger than a second parking electric quantity threshold, if yes, step S823 is followed, and if no, step S824 is followed. In one embodiment, the second parking electric quantity threshold may be 25% of the total electric quantity of the battery group.
At step S823, the electric vehicle is allowed to run under a limited power.
At step S824, the battery management device sends a message to the meter to display that the user stops heating so that the electric vehicle is not allowed to be heated, driven or charged.
At step S825, it is detected whether there is a failure in the battery heater, if yes, step S826 is followed, and if no, step S827 is followed.
At step S826, the battery heater stops working and the meter displays an alarm.
At step S827, it is detected whether the temperature of the battery group is higher than the first heating threshold, if yes, step S830 is followed, and if no, step S828 is followed.
At step S828, it is detected whether the temperature of any single battery in the battery group is higher than the second heating threshold, if yes, step S830 is followed, and if no, step S829 is followed.
At step S829, it is detected whether the total continuous heating time is higher than a heating time threshold, if yes, step S830 is followed, and if no, step S813 is followed.
At step S830, the heating is finished and the battery heater stops working.
In one embodiment of the present disclosure, the first heating threshold may be -10°C, the second heating threshold may be 20°C, and the heating time threshold may be 20 minutes.
In one embodiment of the present disclosure, between step S814 and step S815, the method may further comprise a step of heating the battery group with different heating powers according to different temperatures of the battery group, In general, if the temperature of the batter group 101 is relatively lower, a relatively higher heating power may cause a damage to the batter group 101 as well as result in a poor heating effect. Therefore, by applying different heating powers according to different temperature ranges, a service life of the batter group 101 may be prolonged, a heating efficiency may be improved, and a power consumption is accordingly reduced.
Specifically, when the temperature of the battery group is higher than the third heating threshold and lower than the fourth heating threshold, the battery management device controls the battery heater to heat the battery group with the first power; when the temperature of the battery group is higher than the fourth heating threshold and lower than the fifth heating threshold, the battery management device controls the battery heater to heat the battery group with the second power; when the temperature of the battery group is higher than the fifth heating threshold and lower than the sixth heating threshold, the battery management device controls the battery heater to heat the battery group with the third power; and when the temperature of the battery group is higher than the sixth heating threshold and lower than the seventh heating threshold, the battery management device controls the battery heater to heat the battery group with the fourth power. In one embodiment of the present disclosure, the third temperature threshold may be -30°C, the fourth temperature threshold may be -25°C, the fifth temperature threshold may be -20°C, the sixth temperature threshold may be -15°C, and the seventh temperature threshold may be -10°C. It should be noted that, the first power, the second power, the third power and the fourth power may be set according to actual conditions so as to realize that the battery group is heated efficiently and an influence on the battery group is minor.
In some embodiments, when the electric vehicle is powered on, the battery management device detects the temperature of the battery group and the status of the primary contactor. The temperature of the battery group is an average of temperatures of all single batteries in the battery group. The battery management device samples the temperature of each single battery in the battery group through an information collector and calculates the temperature of the battery group. If the temperature of the battery group is lower than the first heating temperature and the residual electric quantity of the battery group is larger than the parking electric quantity threshold, the user presses and holds the heating button for 2 seconds, and then the battery management device sends a message to the battery heater through the CAN cable to allow the battery group to be heated. In one embodiment of the present disclosure, the first heating threshold may be -10°C, and the parking electric quantity threshold may be 30% of the total electric quantity of the battery group. Before heating the battery group in the running heating mode, that is, before the motor works, the battery management device sends the control signal to the electric distribution box to control the pre-contactor to be switched on so that the battery group charges the pre-charging capacitor C2. When the voltage of the pre-charging capacitor C2 is substantially equal to that of the battery group, the motor is allowed to work.
In one embodiment of the present disclosure, the heating button is disposed on the meter. Provided that the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is larger than the parking electric quantity threshold, when the heating button is pressed, the battery heater is allowed to work. If the heating button is pressed again and held for 2 seconds, the battery heater is forced to stop working.
The primary contactor is disposed in the electric distribution box and configured to connect the motor controller to a power supply or disconnect the motor controller from a power supply. When the residual electric quantity of the battery group is larger than the running electric quantity threshold, the battery management device sends the control signal to the electric distribution box to control the primary contactor to be switched on so that the motor is allowed to work. The motor controller converts the DC to the three-phase AC required by the motor through the driving circuit, to supply power to the motor and to allow the electric vehicle to run under a limited power.
The pre-contactor is also disposed in the electric distribution box and connected to the pre- charging capacitor C2 in series. In particular, the pre-charging capacitor C2 is charged before the motor works. The reasons may be as follows. In one aspect, a current shock may be avoided in the pre-charging procedure and an agglomeration caused when the primary contactor is switched on may be avoided. A current limiting resistor is connected in series between the pre-charging capacitor and the pre-contactor. When the pre-charging is finished, the battery management device controls the primary contactor to be switched on and then controls the pre-contactor to be switched off. In another aspect, since the current is larger at the start moment of the motor, the voltage of the whole battery group is reduced. Therefore, the pre-charging capacitor C2 is charged firstly until the voltage thereof is substantially equal to that of the battery group, and then the motor is started. Because the voltage of the pre-charging capacitor can not change suddenly, by connecting the pre- charging capacitor and the motor in parallel, the affect on the voltage of the battery group resulting from the start of the motor may be decreased.
When the battery heater receives the heating signal sent by the battery management device, the battery heater performs a self-test to detect whether there is a failure in the battery heater. In one embodiment of the present disclosure, the battery heater sends a single pulse of 0.5ms to detect whether there is a failure in the battery heater. If there is not any failure, the battery heater sends a control pulse (for example with a cycle of 20ms and a duty ratio of 20%) to the internal switch module to make the battery group short the circuit in a short time. So the heating purpose is achieved. Meanwhile, the battery heater sends a CAN signal to the meter. The meter receives the CAN signal and displays that "the battery group is being heated".
When the battery group is heated, the battery management device and the battery heater keep on detecting the status of the battery group. If the temperature of the battery group is higher than the first heating threshold, or the continuous heating time is larger than the heating time threshold, or the maximum temperature of a single battery in the battery group is higher than the second heating threshold, the battery heater stops sending the control pulse to the internal switch module to stop heating the battery group. The battery heater sends a CAN signal to the meter. The meter receives the CAN signal and displays that "the heating is finished". The heating procedure is finished. In one embodiment of the present disclosure, the second heating threshold may be 20°C, and the heating time threshold may the 20 minutes. Preferably, in order to avoid a repeated start of the heating procedure, during the heating process, if the temperature of the battery group is detected to be higher than the first heating threshold by 5°C, the battery group is stopped from being heated.
If the temperature of the battery group is higher than the first heating threshold, the battery management device works normally. If the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is less than the parking electric quantity threshold, the primary contactor is not switched on and the battery management device sends the CAN signal to the battery heater and the meter, so that the battery group is not allowed to be heated. When the meter receives the CAN signal, the meter displays that "the residual electric quantity of the battery group is not enough" so that the electric vehicle is not allowed to be heated, driven or charged.
If a failure of the battery heater, including under voltage protection, over- voltage protection, overheat protection, pulse width interval protection or maximum turn-on time protection, appears during the self-test process, it is not allowed to heat the battery group. The battery heater sends a failure signal. The meter receives the failure signal and displays that "a failure in the battery heater". The heating is not allowed.
If any of a failure of the battery heater, including under voltage protection, over-voltage protection, overheat protection, pulse width interval protection or maximum turn-on time protection, appears during the heating process, the battery heater stops heating the battery group and sends a failure signal. The meter receives the failure signal and displays that "a failure in the battery heater". The heating is ceased.
In some embodiments of the present disclosure, the battery heater comprises a protection circuit to prevent the failures mentioned above. The protection circuit will be described in detail as follows.
(1) When there is a failure signal, an IGBT in the battery heater is turned off. An ERROR
(failure) pin of the protection circuit is at a low level, a failure signal is output through an optical coupler, and thus an ERROUT (failure output) pin is at the low level. To release the protection status, the PWM (pulse width modulation) wave should be maintained at a high level for 2 seconds, and then the failure signal is reset and the protection circuit is recovered to a normal status. If the failure signal can not be reset by the PWM wave in 2 seconds, a permanent error occurs in the protection circuit so that the protection circuit can not work normally.
(2) To ensure a normal work of a discharge module of the IGBT, the frequency of the pulse sent by a DSP (digital signal processor) may not be too high and the pulse width may not be too long. For example, the maximum pulse width may be 5ms and the minimum interval may be 7-10 ms, or else a failure signal will be output.
(3) In one embodiment of the present disclosure, a DC-DC isolation power supply is used to drive the IGBT. The positive bias voltage for the gate terminal of the IGBT may be +15V, and the negative bias voltage for the gate terminal of the IGBT may be -7V. The negative bias voltage for the gate terminal of IGBT may turn off the IGBT quickly and avoid a malfunction of turning on IGBT because of the overlarge surge current.
(4) In one embodiment of the present disclosure, the protection circuit comprises an under voltage protection circuit. The under voltage protection circuit may avoid an increase of the power consumption of the IGBT caused by the deficient driving voltage. When the driving voltage decreases to a first voltage threshold, the under voltage protection circuit starts to work. In one embodiment of the present disclosure, the first voltage threshold may be 9V.
(5) The over-heat protection circuit may avoid the damage to the IGBT caused by the high temperature. The protection circuit samples the temperature by using a thermistor. When the temperature of the IGBT is higher than a safe temperature threshold, the over-heat protection circuit starts to work. The protection circuit may also be configured to detect whether there is an open circuit in the thermistor. When there is an open circuit in the thermistor, the equivalent impedance is infinite and a protection signal is output. In one embodiment of the present disclosure, the safe temperature threshold may be 85°C.
(6) Because there is a large inductance in the discharge loop, when the IGBT is turned off, an over-high voltage may be excited by the collector terminal of the IGBT. So a high voltage capacitor is connected in parallel between the collector terminal and the emitter terminal of the IGBT. The over-voltage protection circuit may avoid the over high voltage of the collector terminal to damage the IGBT at the moment of turning off the IGBT. When the voltage of the collector terminal is larger than a second voltage threshold, a protection signal will be output. In one embodiment of the present disclosure, the second voltage threshold may be 800V.
During the heating process of the battery group, if the user suddenly presses and holds the heating button for 2 seconds, the battery heater stops heating the battery group so that the battery group is not allowed to be charged and the electric vehicle is not allowed to be driven.
With the method for heating the battery of the power system of the electric vehicle according to embodiments of the present disclosure, the battery group of the electric vehicle may be heated without any external power supply. The battery group is heated to a required temperature and then may be charged or discharged normally. So the restriction on the use of the electric vehicle at the low temperature may be greatly reduced and the requirements of running and charging at the low temperature may be satisfied. In addition, by heating the battery group with different heating powers according to the real-time temperature of the battery group, a service life of the battery group is prolonged and a power consumption is reduced. Furthermore, by sampling the throttle depth change rate of the electric vehicle and judging whether the output power of the battery group is too large, it is possible to stop heating the battery group when the output power of the battery group is too large, and thus to avoid the over discharging of the battery group. Therefore, the service life of the battery group is prolonged and the dynamic property of the electric vehicle is ensured.
In the preceding specification, the subject matter has been described with reference to specific exemplary embodiments. It will, however, be evident that various modifications and changes may be made without departing from the broader spirit and scope of the claimed subject matter as set forth in the claims that follow. The specification and drawings are accordingly to be regarded as illustrative rather than restrictive. Other embodiments may be apparent to those skilled in the art from consideration of the specification and practice of the embodiments disclosed herein.

Claims

WHAT IS CLAIMED IS:
1. A power system of an electric vehicle, comprising:
a battery group;
a battery heater, connected with the battery group and configured to charge and discharge the battery group to heat the battery group;
a battery management device, connected with the battery group and the battery heater respectively, configured to control the battery heater to heat the battery group intermittently when a temperature of the battery group is lower than a first heating threshold and a residual electric quantity of the battery group is larger than a parking electric quantity threshold, and to control the battery heater to stop heating the battery group according to a current throttle depth change rate of the electric vehicle when the battery group is in a running heating mode;
an electric distribution box, configured to distribute a voltage output by the battery group; a motor;
a motor controller, connected with the motor and the electric distribution box respectively, comprising a first input terminal, a second input terminal and a pre-charging capacitor connected between the first input terminal and the second input terminal, and configured to supply power to the motor according to a control command and a voltage distributed by the electric distribution box; and
an isolation inductor, connected between the battery group and the electric distribution box, wherein an inductance of the isolation inductor matches with a capacitance of the pre-charging capacitor.
2. The power system of claim 1, wherein the battery management device is further configured to control the battery heater to heat the battery group in the running heating mode when the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is larger than a running electric quantity threshold, in which the running electric quantity threshold is larger than parking electric quantity threshold.
3. The power system of claim 1, wherein the battery management device is configured to judge whether the current throttle depth change rate reaches a preset throttle depth change rate threshold and to control the battery heater to stop heating the battery group when the current throttle depth change rate reaches the preset throttle depth change rate threshold.
4. The power system of claim 3, wherein the battery management device is further configured to control the battery heater to continue heating the battery group when the current throttle depth change rate is lower than the preset throttle depth change rate threshold.
5. The power system of claim 4, wherein the battery management device is further configured to judge whether a heating time reaches a first preset time and to control the battery heater to suspend heating the battery group when the heating time reaches the first preset time.
6. The power system of claim 5, wherein the battery management device is further configured to calculate a suspension time after controlling the battery heater to suspend heating the battery group and to control the battery heater to heat the battery group when the suspension time reaches a second preset time.
7. The power system of claim 1, wherein the battery heater is further configured to perform a failure self-test and send a test result to the battery management device.
8. The power system of claim 1, wherein the battery heater comprises:
a first switch module, a first terminal of the first switch module connected with a first electrode of the battery group and the isolation inductor respectively;
a first capacitor, a first terminal of the first capacitor connected with a second terminal of the first switch module, and a second terminal of the first capacitor connected with a second electrode of the battery group;
a first inductor, a first terminal of the first inductor connected with a node between the first switch module and the first capacitor; and
a second switch module, a first terminal of the second switch module connected with a second terminal of the first inductor, and a second terminal of the second switch module connected with the second electrode of the battery group,
wherein a control terminal of the first switch module and a control terminal of the second switch module are connected with the battery management device, and the battery management device sends a heating signal to the control terminal of the first switch module and the control terminal of the second switch module to control the first switch module and the second switch module to turn on in turn so as to generate a charge current and a discharge current in turn, in which the first switch module is on when the second switch module is off, and the first switch module is off when the second switch module is on.
9. The power system of claim 8, wherein the battery heater further comprises a cooling assembly configured to cool the first switch module and the second switch module.
10. The power system of claim 9, wherein the cooling assembly comprises:
a wind channel arranged in the battery heater; and
a fan arranged at one end of the wind channel.
11. The power system of claim 9, wherein the cooling assembly comprises:
a coolant channel arranged in the battery heater; and
a coolant inlet and a coolant outlet arranged in the battery heater.
12. The power system of claim 1, wherein the battery heater further comprises a power connector configured to connect and fasten a power cable connected to the battery group.
13. The power system of claim 1, wherein the electric distribution box comprises:
a primary contactor, configured to distribute the voltage output by the battery group to a power consumption equipment of the electric vehicle; and
a pre-contactor, connected with the first input terminal or the second input terminal of the motor controller, and configured to charge the pre-charging capacitor under a control of the battery management device before the motor controller controls the motor to start.
14. An electric vehicle comprising a power system of any one of claims 1-13.
15. A method for heating a battery group of an electric vehicle, comprising:
detecting a temperature and a residual electric quantity of the battery group;
if the temperature of the battery group is lower than a first heating threshold and the residual electric quantity of the battery group is larger than a parking electric quantity threshold, controlling a battery heater to heat the battery group intermittently ;
controlling the battery heater to stop heating the battery group according to a current throttle depth change rate when the battery group is in a running heating mode; and
if the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is lower than the parking electric quantity threshold, indicating the battery group is inhibited from being heated or charged and the electric vehicle is inhibited from being driven.
16. The method of claim 15, further comprising:
controlling the battery heater to heat the battery group in the running heating mode when the temperature of the battery group is lower than the first heating threshold and the residual electric quantity of the battery group is larger than a running electric quantity threshold, in which the running electric quantity threshold is larger than the parking electric quantity threshold.
17. The method of claim 15, further comprising:
judging whether the current throttle depth change rate reaches a preset throttle depth change rate threshold;
if yes, controlling the battery heater to stop heating the battery group; and
if no, controlling the battery heater to continue heating the battery group.
18. The method of claim 15, further comprising:
judging whether a heating time reaches a first preset time; and
if yes, controlling the battery heater to suspend heating the battery group.
19. The method of claim 18, further comprising:
calculating a suspension time after controlling the battery heater to suspend heating the battery group;
judging whether the suspension time reaches a second preset time; and
if yes, controlling the battery heater to heat the battery group.
20. The method of claim 15, further comprising:
performing a failure self-test for the battery heater; and
indicating the battery group is inhibited from being heated or charged and the electric vehicle is inhibited from being driven if a failure is detected in the battery heater.
21. The method of claim 15, further comprising:
calculating a current temperature of the battery group and a current residual electric quantity of the battery group;
calculating a maximum output power of the battery group according to the current temperature of the battery group and the current residual electric quantity of the battery group; and controlling the electric vehicle to run under a limited power according to the maximum output power of the battery group.
22. The method of claim 15, further comprising: controlling the battery heater to stop heating the battery group when any of following conditions is satisfied:
the temperature of the battery group is higher than the first heating threshold;
a temperature of any single battery in the battery group is higher than a second heating threshold, wherein the second heating threshold is larger than the first heating threshold; and
a continuous heating time of the battery heater is larger than a heating time threshold.
PCT/CN2013/076117 2012-05-22 2013-05-22 Power system of electric vehicle, electric vehicle comprising the same and method for heating battery group of electric vehicle WO2014005470A1 (en)

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Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3112665A3 (en) * 2015-04-30 2017-03-15 Modern Home Lighting Inc. Car starter which works under very low temperature and a protection circuit thereof
EP3686051A4 (en) * 2018-11-27 2021-01-13 Risesun Mengguli New Energy Science & Technology Co., Ltd. Battery system with adjustable heating rate and control method thereof
CN112622652A (en) * 2019-09-24 2021-04-09 长城汽车股份有限公司 Charging control method and device
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WO2022266912A1 (en) * 2021-06-24 2022-12-29 华为技术有限公司 Battery heating method and heating apparatus
CN115764812A (en) * 2022-12-26 2023-03-07 广州市德珑电子器件有限公司 Automatic protection method for switching power supply and switching power supply
CN116577676A (en) * 2023-07-14 2023-08-11 中国第一汽车股份有限公司 Battery parameter determining method and device, processor and vehicle

Families Citing this family (18)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104709091B (en) * 2013-12-13 2017-04-05 北汽福田汽车股份有限公司 The upper electric and lower method for electrically of pure electric vehicle
CN104377402B (en) * 2014-12-02 2017-01-11 天津航空机电有限公司 Control and fault diagnosing system of battery heater
CN105449312B (en) * 2015-10-13 2019-05-14 华富(江苏)锂电新技术有限公司 A kind of heating control circuit for lithium ion battery
CN106356921B (en) * 2016-08-31 2019-06-18 北京新能源汽车股份有限公司 Power-discharging circuit and method of electric automobile and electric automobile
CN109713400A (en) * 2017-10-26 2019-05-03 北京长城华冠汽车科技股份有限公司 Determine the electric automobile power battery heating means of minimum power consumption
CN108736107B (en) 2018-05-22 2020-06-23 宁德时代新能源科技股份有限公司 Heating module, battery pack heating method and heating system
CN109378873B (en) * 2018-11-02 2022-05-31 上海芯凌微电子有限公司 Battery charging system and charging method
CN112563623A (en) * 2018-11-30 2021-03-26 宁德时代新能源科技股份有限公司 Battery heating system
CN109830783B (en) * 2019-01-25 2021-06-22 江苏大学 Whole vehicle heat management system based on college student electric formula car and control method thereof
CN111509323A (en) * 2019-01-30 2020-08-07 雷达 Graphene thermal management method for new energy automobile power battery
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CN113745701B (en) * 2020-05-29 2024-08-06 比亚迪股份有限公司 Heating method and device of power battery, controller and vehicle
CN114374024A (en) * 2021-12-31 2022-04-19 优跑汽车技术(上海)有限公司 Heating control method and device for power battery and electric automobile
CN114935203A (en) * 2022-06-09 2022-08-23 重庆伏特猫科技有限公司 Intelligent environment temperature control device based on air conditioner control and use method thereof

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7154068B2 (en) * 2004-05-26 2006-12-26 Ford Global Technologies, Llc Method and system for a vehicle battery temperature control
US20090179616A1 (en) * 2006-07-10 2009-07-16 Toyota Jidosha Kabushiki Kaisha Power Supply System, Vehicle with the Same and Temperature Managing Method
CN101885313A (en) * 2010-07-14 2010-11-17 李辉 Thermal management system of electric automobile
CN101931100A (en) * 2009-06-18 2010-12-29 比亚迪股份有限公司 Battery pack
CN102055042A (en) * 2009-10-29 2011-05-11 比亚迪股份有限公司 Battery heating control system for vehicles and control method thereof

Family Cites Families (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20090071178A1 (en) * 2007-09-14 2009-03-19 Gm Global Technology Operations, Inc. Vehicle HVAC and Battery Thermal Management
CN201400078Y (en) * 2009-05-08 2010-02-10 比亚迪股份有限公司 Electric vehicle
US9162558B2 (en) * 2009-06-15 2015-10-20 Polaris Industries Inc. Electric vehicle
CN102416882B (en) * 2011-12-05 2014-08-13 郑州宇通客车股份有限公司 High-tension distribution box for pure electric vehicle

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7154068B2 (en) * 2004-05-26 2006-12-26 Ford Global Technologies, Llc Method and system for a vehicle battery temperature control
US20090179616A1 (en) * 2006-07-10 2009-07-16 Toyota Jidosha Kabushiki Kaisha Power Supply System, Vehicle with the Same and Temperature Managing Method
CN101931100A (en) * 2009-06-18 2010-12-29 比亚迪股份有限公司 Battery pack
CN102055042A (en) * 2009-10-29 2011-05-11 比亚迪股份有限公司 Battery heating control system for vehicles and control method thereof
CN101885313A (en) * 2010-07-14 2010-11-17 李辉 Thermal management system of electric automobile

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3112665A3 (en) * 2015-04-30 2017-03-15 Modern Home Lighting Inc. Car starter which works under very low temperature and a protection circuit thereof
EP3686051A4 (en) * 2018-11-27 2021-01-13 Risesun Mengguli New Energy Science & Technology Co., Ltd. Battery system with adjustable heating rate and control method thereof
CN112622652A (en) * 2019-09-24 2021-04-09 长城汽车股份有限公司 Charging control method and device
WO2022266912A1 (en) * 2021-06-24 2022-12-29 华为技术有限公司 Battery heating method and heating apparatus
CN114564055A (en) * 2022-04-27 2022-05-31 深圳市飞梵实业有限公司 Nasal feeding nutrition pump temperature control system
CN115764812A (en) * 2022-12-26 2023-03-07 广州市德珑电子器件有限公司 Automatic protection method for switching power supply and switching power supply
CN116577676A (en) * 2023-07-14 2023-08-11 中国第一汽车股份有限公司 Battery parameter determining method and device, processor and vehicle
CN116577676B (en) * 2023-07-14 2023-09-22 中国第一汽车股份有限公司 Battery parameter determining method and device, processor and vehicle

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