This invention provides a kind of compact type fuel cell supply system, consisting of fuel cell, DCDC converting unit, contactor, energy storage device, controller, auxiliary system, power supply output end, operation control unit, with the contactor being a normal open type high-current contactor,
This invention provides a kind of compact type fuel cell supply system, consisting of fuel cell, DCDC converting unit, contactor, energy storage device, controller, auxiliary system, power supply output end, operation control unit, with the contactor being a normal open type high-current contactor, the output end of the fuel cell connecting the input end of DCDC converting unit, the DCDC converting unit connecting the energy storage device through the contactor, the output end of DCDC converting unit also connecting the power supply output end and the high-power auxiliary component that the auxiliary system contains, the port of the energy storage device connecting the power supply output end and auxiliary system through the contactor, the operation control unit connecting the energy storage device, DCDC converting unit, controller respectively, the controller connecting the fuel cell, DCDC converting unit, the control end of contactor, the energy storage device and the auxiliary system respectively. This invention, through reducing parts and components, improves system reliability and decreases the volume to make a system have a sufficient space for installation and maintenance, which favors heat dissipation of electronic parts and components. This invention is applicable to forklift in particular.
대표청구항▼
1. A fuel cell mixed power supply energy management method implemented with a processor and memory includes the following steps: Step S201: Initialize, specifically, obtain the following parameter values first:The first current setting of DCDC Isetmin,The first voltage setting of energy storage devi
1. A fuel cell mixed power supply energy management method implemented with a processor and memory includes the following steps: Step S201: Initialize, specifically, obtain the following parameter values first:The first current setting of DCDC Isetmin,The first voltage setting of energy storage device Umax,The second voltage setting of energy storage device Umin,The permissible DCDC current deviation value Ipermissible,The maximum current setting that DCDC allows to output Imax,Then let the current setting of DCDC Iset equal to the said first current setting of DCDC Isetmin;Step S202: Obtain the energy storage device voltage Ustorage and the actual output current of DCDC converting unit Idcdc, calculate according to the following formula (1) DCDC current deviation value Ideviation: Ideviation=Iset−Idcdc Formula (1);Step S203: in case of meeting the following circumstances, enter into Step S204, Step S205 or Step S206:If the energy storage device voltage Ustorage is greater than or equal to the first voltage setting of energy storage device Umax, then enter into Step S204,If the energy storage device voltage Ustorage is less than or equal to the first voltage setting of energy storage device Umin, then enter into Step S205,If the energy storage device voltage Ustorage is less than the first voltage setting of energy storage device Umax and greater than the first voltage setting of energy storage device Umin, and the DCDC current deviation value Ideviation is greater than or equal to the permissible DCDC current deviation value Ipermissible, then enter into Step S206,If the energy storage device voltage Ustorage is less than the first voltage setting of energy storage device Umax and greater than the first voltage setting of energy storage device Umin, and the DCDC current deviation value Ideviation is less than the permissible DCDC current deviation value Ipermissible, then enter into Step S207;Step S204: If the current setting of DCDC Iset is greater than the first current setting of DCDC Isetmin, then gradually reduce the current setting of DCDC Iset, and then enter into Step S207; if the current setting of DCDC Iset is less than or equal to the first current setting of DCDC Isetmin, then let the current setting of DCDC Iset is equal to the said first current setting of DCDC Isetmin and then enter into Step S207;Step S205: If the current setting of DCDC Iset is less than the maximum current setting that DCDC allows to output Imax, increase the current setting of DCDC Iset and then enter into Step S207; if the current setting of DCDC Iset is greater than or equal to the maximum current setting that DCDC allows to output Imax, let the current setting of DCDC Iset equal to the maximum current setting that DCDC allows to output Imax and then enter into Step S207;Step S206: If the current setting of DCDC Iset is greater than the first current setting of DCDC Isetmin, reduce at a fastest speed the current setting of DCDC Iset and then enter into Step S207; if the current setting of DCDC Iset is less than or equal to the first current setting of DCDC Isetmin, let the current setting of DCDC Iset equal to the said first current setting of DCDC Isetmin and then enter into Step S207;Step S207: Send a current setting instruction to DCDC converting unit, in which the said current setting instruction is used to set the output current of the DCDC converting unit as the current setting of DCDC Iset and then return to Step S202. 2. According to claim 1, before the said Step S201, the following steps executed in proper order are also included: Step A1: Determine the limit voltage Ulim, specifically, judge if the highest limit of load protection voltage is greater than the charging protection voltage of the energy storage device; if the judgment result is positive, set the limit voltage Ulimit as equal to the charging protection voltage of the energy storage device; if the judgment result is negative, set the limit voltage Ulimit as equal to the highest limit of load protection voltage;Step A2: Determine the expected DCDC converting unit output current Iexpect according to the following formula (2): Iexpect=Irated·EdcdcUlim,Formula(2)Where Irated is the rated output power of the fuel cell, Edcdc is the efficiency of the DCDC converting unit;Step A3:On the current curve using expected DCDC converting unit output current as a constant charging value, obtain the corresponding charging capacity as 50%-90% of the voltage interval, select any voltage value in the voltage interval as the first voltage setting of energy storage device Umax. 3. According to claim 1, in the said Step A3, from the corresponding charging capacity being any voltage value or voltage interval below, set the said voltage value as or select any voltage value in the said voltage interval as the first voltage setting of energy storage device Umax: The corresponding charging capacity is the voltage value at 90%, determine the voltage value at the said 90% as the first voltage setting of energy storage device Umax, The corresponding charging capacity is 60%-80% voltage interval, select any voltage value in the said 60%-80% voltage interval to be determined as the first voltage setting of energy storage device Umax,The corresponding charging capacity is 80%-90% voltage interval, select any voltage value in the said 80%-90% voltage interval to be determined as the first voltage setting of energy storage device Umax,The corresponding charging capacity is 50%-60% voltage interval, select any voltage value in the said 50%-60% voltage interval to be determined as the first voltage setting of energy storage device Umax. 4. According to claim 1, before the said Step S201, the following steps executed in proper order are also included: Step B1: Determine the system limit charging current, specifically,Under the working condition in which the system uses medium limit energy recovery, first use battery to make a braking action and obtain the system current, time data from braking to the end, the negative current of that system is the charging current, calculate the average of that charging current as the system limit charging current;Step B2: Determine the limit voltage Ulim, specifically, judge if the highest limit of load protection voltage is greater than the charging protection voltage of the energy storage device; if the judgment result is positive, set the limit voltage Ulimit as equal to the charging protection voltage of the energy storage device; if the judgment result is negative, set the limit voltage Ulimit as equal to the highest limit of load protection voltage;Step B3: Determine the expected DCDC converting unit output current Iexpect according to the following formula (2): Iexpect=Irated·EdcdcUlim,Formula(2)Where Irated is the rated output of the fuel cell, Edcdc is the efficiency of the DCDC converting unit;Step B4: Inquire the testing curves of different charging currents and charging capacitances; according to the constant current charging curve that the system limit charging current corresponds to, obtain the corresponding charging capacitance when charging to the limit voltage; according to that charging capacity, look up the corresponding voltage value on the constant current charging curve that the expected DCDC converting unit output current Iexpect corresponds to, the said corresponding voltage value is the first voltage setting of energy storage device Umax;Step B5: According to the energy recovery working condition when the system uses time limit, do actual testing by using the system controlled by the first voltage setting of energy storage device Umax, correct the first voltage setting of energy storage device Umax so that the actually measured highest voltage is slightly lower than the limit voltage Ulim;Step B6: Correct the capacity of the energy storage device, specifically, according to the relational curve between energy storage device charging capacity/rated capacity and cycle times, or the relational curve between the discharging capacity/rated capacity and cycle times, inquire the charging capacity/rated capacity ratio after multiple cycles, and then take the product of the first voltage setting of energy storage device Umax and the charging capacity/rated capacity ratio as the corrected first voltage setting of energy storage device Umax. 5. According to claim 1, before the said Step S201, the following steps executed in proper order are also included: Step C1: Determine the minimum consumption current of the auxiliary system Is, specifically, use the system controlled by the first voltage setting of energy storage device Umax to have the system be in an idle condition, after the system becomes stable, the consumption of the auxiliary system reduces to the minimum, measure the current of the auxiliary system at this time, which is the minimum consumption current;Step C2: take the product of the minimum consumption current of the auxiliary system and the coefficient K as the first current setting of DCDC Isetmin, where the coefficient K is less than 1. 6. According to claim 1, the coefficient K is 0.6. 7. According to claim 1, before the said Step S201, the following steps executed in proper order are also included: Step D1: Determine according to the follow formula (3) the maximum current setting that DCDC allows to output Imax: Imax=Irated·EdcdcUmax.Formula(3) 8. According to claim 1, before the said Step S201, the following steps executed in proper order are also included: Step E1: Determine according to the following formula (4) the capacitance at the minimum load Cmin: Cmin=C−(Is−Iset min)·T Formula (4)Where, C is the charging capacity, Is is the minimum consumption current of the auxiliary system, T is time, the said charging capacity is the charging capacity that the first voltage setting of energy storage device Umax corresponds to inquired on the charging capacity and charging voltage curve with constant current charging taking the maximum current setting that DCDC allows to output Imax as the current, the said time is set according to the response speed that the system requires;Step E2: According to the capacitance at minimum load Cmin, inquire the charging voltage that the capacitance at the minimum load Cmin corresponds to on the charging capacity and charging voltage curve with constant current charging taking the maximum current setting that DCDC allows to output Imax as the current, select that charging voltage as the second voltage setting of energy storage device Umin.
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