CN201680967U - Multi-energy hybrid integrated experiment device - Google Patents

Multi-energy hybrid integrated experiment device Download PDF

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Publication number
CN201680967U
CN201680967U CN2010201959003U CN201020195900U CN201680967U CN 201680967 U CN201680967 U CN 201680967U CN 2010201959003 U CN2010201959003 U CN 2010201959003U CN 201020195900 U CN201020195900 U CN 201020195900U CN 201680967 U CN201680967 U CN 201680967U
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controller
control
motor
engine
test
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冯能莲
宾洋
张潇
周大森
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Beijing University of Technology
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Beijing University of Technology
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Abstract

The utility model relates to a multi-energy hybrid integrated experiment device, belonging to the field of automobile dynamic performance testing, and relating to an integrated experiment device concurrently provided with a calibration system and an energy recovery system. Main parts of the integrated experiment device consists of an engine (1), a torque converter (2), a sensor (3), motors (4 and 9), a sensor (5), a dynamometer (6), a brake (7), an inertia disk (8) and a sensor (10) which are connected on a same shaft through a coupling (16), as well as two rectifying inverters (11 and 12), a battery-supercapacitor (13), an engine ECU (14), an integrated control system (18) and the calibration system (29). The experiment device can simulate operating conditions of most of hybrid automobiles, and provide an experimental platform for the development of the hybrid automobiles. Simultaneously, the experiment device also provides the experimental platform for the coordinated matching of the hybrid automobiles with a plurality of controllers, braking systems and control methods. The experiment device can complete nearly ten calibrating experiments related to automobile dynamic performance testing.

Description

Multi-energy hybrid power comprehensive test device
Technical field
The utility model relates to a kind of multi-energy hybrid power comprehensive test device, especially a kind of combined test apparatus with calibration system and energy-recuperation system.
Background technology
In recent years, because environmental pollution and energy shortage problem become increasingly conspicuous, impel auto industry to develop towards low consumption, low emission, high efficiency direction, one of developing direction is exactly a mixed power electric car, and it has the two-fold advantage of good dynamic property of traditional fuel-engined vehicle and electric motor car low emission.Mixed power electric car has two kinds of power sources, and traditional single power source test-bed can not satisfy the needs of hybrid power test, and the multi power source test-bed of development of new could satisfy the requirement of hybrid power test.Existing hybrid power test-bed, the overwhelming majority develops at a certain connected mode, or the serial mixed power test-bed, or the parallel type hybrid dynamic test-bed.No matter which kind of test-bed all has only two power sources, and one is engine, and one is motor.These two kinds of test-beds all have significant limitation, are embodied in to do the hybrid power test under fixedly connected mode, and both advantages of (tandem, parallel) can not be combined, and can't give full play to the advantage of mixed power electric car.Control system plays crucial effects in multiple power source test-bed, for the control of multipotency driving source assembly, the promptness of control and levels of precision can cause the quality of hybrid power test findings.Good control system can improve the accuracy of test, and energy savings reduces discharging, improves energy utilization ratio.Though existing control system can make test carry out smoothly, can not make test findings reach optimization.
Summary of the invention
The purpose of this utility model is to provide a kind of multi-energy hybrid power comprehensive test device, and this test unit can carry out the hybrid power test of multiple mode, simultaneously can also recovery section mechanical energy, convert it into electrical power storage.
To achieve these goals, the technical solution adopted in the utility model is: design a kind of multi-energy hybrid power comprehensive test device, comprise engine, torque converter, sensor, motor 1-2, sensor, dynamometer machine, detent, the inertia dish, sensor, two rectification adverser 1-2, battery-super electric capacity, Engine ECU, and by Engine ECU controller ETC, torque converter controller TCU, three sensor digital to analog converter DA1-3, two electric machine controller MC1-2, battery management unit BCM, Dynamometer Control device DYM, brake controller ABS, the integrated control system that the CAN bus is formed.And engine, torque converter, sensor, motor 1, sensor, dynamometer machine, detent, inertia dish, motor 2 and sensor are coaxial successively by the shaft coupling mechanical connection, and are connected with transmission shaft; Wherein, motor 1 is connected with rectification adverser 1 circuit, rectification adverser 1 is connected with the battery-super condenser network, battery and super capacitor are connected in parallel, motor 2 is connected with rectification adverser 2 circuit, rectification adverser 2 is connected with the battery-super condenser network, Engine ECU controller ETC is connected with the Engine ECU circuit, gearbox controller TCU is connected with the variator circuit, sensor digital to analog converter DA1 is connected with sensor circuit, electric machine controller MC1 is connected with rectification adverser 1 circuit, battery management unit BCM is connected with the battery-super condenser network, sensor digital to analog converter DA1 is connected with sensor circuit, Dynamometer Control device DYM is connected with the dynamometer machine circuit, brake controller ABS is connected with brake circuit, electric machine controller MC2 is connected with rectification adverser 2 circuit, sensor digital to analog converter DA3 is connected with sensor circuit, Engine ECU controller ETC, torque converter controller TCU, sensor digital to analog converter DA1, electric machine controller MC1, battery management unit BCM, sensor digital to analog converter DA2, Dynamometer Control device DYM, brake controller ABS, electric machine controller MC2 is connected with the CAN bus circuit with sensor digital to analog converter DA3.
Also be provided with the calibration system that is connected with the integrated control system circuit by the CAN bus in this device, this calibration system is for having real-time demonstration test figure, and by adjust, the optimal control parameter is complementary integrated control system and multipotency driving source assembly, improves the PC of test findings function.
Engine in the above-mentioned multi-energy hybrid power comprehensive test device, torque converter, sensor, motor 1-2, sensor, dynamometer machine, detent, inertia dish, sensor, two rectification adverser 1-2, battery-super electric capacity, Engine ECU, the various combination of Engine ECU controller ETC, torque converter controller TCU, three sensor digital to analog converter DA1-3, two electric machine controller MC1-2, battery management unit BCM, Dynamometer Control device DYM, brake controller ABS connects can be constructed as follows the rating test device:
(1) the rating test device of engine performance test and Engine ECU controller ETC
Disconnect the shaft coupling between engine and the variator, Engine ECU is connected with engine, Engine ECU controller ETC links to each other with Engine ECU and is connected on the CAN bus, communicates by letter with calibration system, becomes the rating test device of engine performance test and Engine ECU controller ETC.
(2) the rating test device of transmission performance test and gearbox controller TCU
Disconnect the shaft coupling between sensor and the motor 1, the torque of engine output is delivered on the output shaft through variator, torque rotary speed on the sensor measurement transmission shaft, gearbox controller TCU is connected with variator, becomes the rating test device of transmission performance test and gearbox controller TCU.
(3) motor properties test and to the rating test device of electric machine controller MC1
Disconnect the shaft coupling between sensor and the motor 1, disconnect the shaft coupling between dynamometer machine and the detent, electric machine controller MC1 is connected with rectification adverser 1 with motor, battery-super electric capacity is connected with rectification adverser 1, becomes the performance test of motor 1 and to the rating test device of electric machine controller MC1.
(4) the rating test device of pure direct motor drive test and electric machine controller MC1
Shaft coupling between open slew device and the sensor, disconnect the shaft coupling between inertia dish and the motor 2, electric machine controller MC1 is connected with rectification adverser 1 with motor 1, battery-super electric capacity is connected with rectification adverser 1, for motor 1 provides electric power, become the rating test device of pure direct motor drive test and electric machine controller MC1.
(5) the rating test device of control system under the serial mixed power pattern
Disconnect the shaft coupling between motor 1 and the sensor, Engine ECU controller ETC control Engine ECU makes power be exported by engine, arrive motor 1 through variator and sensor passes, electric machine controller MC1 control motor 1 is operated in generating state, control rectification adverser 1 simultaneously and be operated in inverter mode, motor 1 changes into electric energy with mechanical energy, stores in the battery through rectification adverser 1; Provide electric power by battery, electric machine controller MC2 control rectification adverser 2 is operated in rectification state, controls motor 2 simultaneously and is operated in motoring condition, and electric energy is changed into mechanical energy output, is delivered to dynamometer machine through inertia dish and detent; Become serial mixed power performance test and the rating test device of integrated control system under the serial mixed power pattern to forming by Engine ECU controller ETC, electric machine controller MC1, torque converter controller TCU, battery management unit BCM, electric machine controller MC2.
(6) the rating test device of control system under the parallel type hybrid dynamic pattern
Disconnect the shaft coupling between dynamometer machine and the detent, disconnect battery and be connected with circuit between the rectification adverser 2, power is provided separately by engine or motor 1; When engine provides power, Engine ECU controller ETC control Engine ECU makes engine output power, the required torque of torque converter controller TCU control variator output test, power is through variator, sensor, motor 1 and sensor, be delivered to dynamometer machine, electric machine controller MC1 control motor 1 makes it be in generating state, controls rectification adverser 1 simultaneously and is operated in inverter mode, is the charging of battery-super electric capacity; When motor 1 provides power, electric machine controller MC1 control motor 1 is operated in motoring condition, and control rectification adverser 1 is operated in rectification state, provide electric power by battery, motor 1 changes into mechanical energy output with electric energy, outputs to dynamometer machine through transmission shaft, at this moment, Engine ECU controller ETC control Engine ECU makes engine be in off position, and torque converter controller TCU control variator is in neutral position, and the cut-out variator is connected with engine; Become parallel type hybrid dynamic automobile performance test and the rating test device of integrated control system under the parallel type hybrid dynamic pattern to forming by Engine ECU controller ETC, torque converter controller TCU, electric machine controller MC1 and battery management unit BCM.
(7) the rating test device under the performance test of series parallel hybrid power automobile and the series parallel hybrid power pattern
Do not disconnect each shaft coupling, control, make test unit be operated in the series-parallel connection state by integrated control system; When Engine ECU controller ETC control Engine ECU makes engine output power, torque converter controller TCU control variator is exported required torque, electric machine controller MC1 control motor 1 is operated in generating state, and control rectification adverser 1 is operated in inverter mode, the power storage that motor 1 is transformed is in battery, electric machine controller MC2 control motor 2 is operated in generating state, controls inversion rectifier 2 simultaneously and is operated in inverter mode, is battery charge; When Engine ECU controller ETC control Engine ECU makes engine be in off position, torque converter controller TCU control variator is in neutral position, cut-out is connected with engine, provide electric power by battery-super electric capacity, electric machine controller MC2 control rectification adverser 2 is operated in rectification state, control motor 2 simultaneously and be operated in motoring condition, motor 2 changes into mechanical energy with electric energy and is delivered to output shaft, electric machine controller MC1 control rectification adverser 1 is operated in inverter mode, control motor 1 is operated in generating state, and the mechanical energy on the transmission shaft is changed into power storage in battery-super electric capacity; Become the performance test of series parallel hybrid power automobile and to Engine ECU controller ETC, torque converter controller TCU, electric machine controller MC1, battery management unit BCM, Dynamometer Control device DYM and the rating test device of electric machine controller MC2 under the series parallel hybrid power pattern.
(8) performance test of combined type hybrid vehicle and the control system rating test device under the combined type hybrid mode
Do not disconnect each shaft coupling; When Engine ECU controller ETC control Engine ECU makes engine output power, the rotating speed that torque converter controller TCU control variator output test needs, make electric machine controller MC1 control motor 1 be operated in generating state or motoring condition, control rectification adverser 1 simultaneously and be operated in inverter mode or rectification state, electric machine controller MC2 control motor 2 is operated in generating state or motoring condition, controls rectification adverser 2 simultaneously and is operated in inverter mode or rectification state; When power was provided by motor 1, Engine ECU controller ETC control Engine ECU made engine be in off position, and torque converter controller TCU control variator is in neutral position, and cut-out is connected with engine, and motor 2 is in generating state; In like manner, when power was provided by motor 2, motor 1 was in generating state; Become the performance test and the rating test device of integrated control system under the combined type hybrid mode of combined type hybrid vehicle to forming by Engine ECU controller ETC, torque converter controller TCU, electric machine controller MC1, battery management unit BCM, Dynamometer Control device DYM, electric machine controller MC2.
(9) braking energy recovery test device
Shaft coupling between open slew device and the sensor, motor 1 is as motor, according to the different tests requirement, 1 output constant torque or the time dependent torque of electric machine controller MC1 may command motor, and the size according to simulation different vehicle inertia is changed different inertia dishes, becomes braking energy recovery test device.
The beneficial effects of the utility model: owing to engine, variator, motor 1, dynamometer machine, detent, motor 2 coaxial installations, battery-super electric capacity links to each other with rectification adverser 1,2, rectification adverser 1,2 links to each other with motor 1,2 respectively, can carry out the rating test of engine performance test, transmission performance test, motor performance test, pure direct motor drive performance test, engine and the test of motor hybrid power, braking energy recovery test and control system.Not only enriched the function of multi-energy hybrid power test-bed, also improved battery structure, super capacitor in parallel; can reclaim braking energy fast, and can provide instantaneous high-power, the protection battery; prolong the serviceable life of battery, reduce energy resource consumption, improve capacity usage ratio.Also increased calibration system, control system and multipotency driving source assembly are complementary, have improved test findings, convenient simultaneously conversion operations different tests, the better operating condition of simulation hybrid vehicle is for the exploitation of hybrid vehicle provides a test platform.This test-bed is simple in structure, and is easy for installation, can simulate most operating modes of mixed power electric car, makes test findings better.
Description of drawings
Fig. 1 is a structural representation of the present utility model
Among the figure: the 1-engine, the 2-variator, the 3-sensor, 4-motor 1,5-sensor 1, the 6-dynamometer machine, the 7-detent, 8-inertia dish, 9-motor 2,10-sensor 2,11-rectification adverser 1,12-rectification adverser 2,13-battery-super electric capacity, the 14-Engine ECU, the 15-transmission shaft, the 16-shaft coupling, the 17-CAN bus, the 18-integrated control system, 19-Engine ECU controller ETC, 20-torque converter controller TCU, 21-sensor digital to analog converter DA1,22-electric machine controller MC1,23-battery management unit BCM, 24-sensor digital to analog converter DA2,25-Dynamometer Control device DYM, 26-brake controller ABS, 27-electric machine controller MC2,28-sensor digital to analog converter DA3, the 29-calibration system.
Embodiment
The utility model is described in further detail below in conjunction with accompanying drawing:
As shown in Figure 1, in multi-energy hybrid power comprehensive test device, the coaxial successively mechanical connection of engine 1, torque converter 2, sensor 3, motor 4, sensor 5, dynamometer machine 6, detent 7, inertia dish 8, motor 9 and sensor 10, connect by shaft coupling 16 between adjacent part input shaft and the output shaft, and be connected with transmission shaft 15.
Integrated control system 18 is made up of Engine ECU controller ETC19, torque converter controller TCU20, two sensor digital to analog converter DA (21,24,28), two electric machine controller MC (22,27), battery management unit BCM23, Dynamometer Control device DYM25, brake controller ABS26, CAN bus 17.
Also comprise two rectification adversers 11,12, battery-super electric capacity 13, Engine ECU 14 in the device, and calibration system 29.
Calibration system comprises PC, data collecting card and calibration software.Data collecting card is installed on the PC, and is connected with CAN bus in the integrated control system by interface.Test figure is delivered on the data collecting card by the CAN bus, and by calibration software with data presentation on PC.Calibration software is complementary integrated control system and multipotency driving source assembly by changing relevant controlled variable, improves test findings, realizes the demarcation to integrated control system.
More than each parts connected mode be: motor 4 is connected with rectification adverser 11 circuit, rectification adverser 11 is connected with battery-super electric capacity 13 circuit, battery and super capacitor are connected in parallel, motor 9 is connected with rectification adverser 12 circuit, rectification adverser 12 is connected with battery-super electric capacity 13 circuit, Engine ECU controller ETC19 is connected with Engine ECU 14 circuit, gearbox controller TCU20 is connected with variator 2 circuit, sensor digital to analog converter DA21 is connected with sensor 3 circuit, electric machine controller MC22 is connected with rectification adverser 11 circuit, battery management unit BCM23 is connected with battery-super electric capacity 13 circuit, sensor digital to analog converter DA24 is connected with sensor 5 circuit, Dynamometer Control device DYM25 is connected with dynamometer machine 6 circuit, brake controller ABS26 is connected with detent 7 circuit, electric machine controller MC27 is connected with rectification adverser 12 circuit, sensor digital to analog converter DA28 is connected with sensor 10 circuit, Engine ECU controller ETC19, torque converter controller TCU20, sensor digital to analog converter DA21, electric machine controller MC22, battery management unit BCM23, sensor digital to analog converter DA24, Dynamometer Control device DYM25, brake controller ABS26, electric machine controller MC27 is connected with CAN bus 17 circuit with sensor digital to analog converter DA28, and CAN bus 17 is connected with calibration system 29 circuit.
Concrete principle of work is as follows:
1, engine performance test: disconnect the shaft coupling 16 between engine 1 and the variator 2, Engine ECU 14 is connected with engine 1, and Engine ECU controller ETC19 links to each other with Engine ECU 14 and is connected on the CAN bus 17, communicates by letter with calibration system 29.This arrangement can carry out the rating test of engine performance test and Engine ECU controller ETC19.
2, transmission performance test: disconnect the shaft coupling 16 between sensor 3 and the motor 4, the torque of engine 1 output is delivered on the output shaft through variator 2, the torque rotary speed that sensor 3 is measured on the transmission shaft, and gearbox controller TCU20 is connected with variator 2.This arrangement can carry out the rating test of transmission performance test and gearbox controller TCU20.
3, motor performance test: disconnect the shaft coupling 16 between sensor 3 and the motor 4, disconnect the shaft coupling between dynamometer machine 6 and the detent 7, electric machine controller MC22 is connected with rectification adverser 11 with motor 4, and battery-super electric capacity 13 is connected with rectification adverser 11.This arrangement can carry out motor properties test and to the rating test of electric machine controller 22.
4, pure direct motor drive test: the shaft coupling 16 between open slew device 2 and the sensor 3, disconnect the shaft coupling between inertia dish 8 and the motor 9, electric machine controller MC22 is connected with rectification adverser 11 with motor 4, and battery-super electric capacity 13 is connected with rectification adverser 11, for motor 4 provides electric power.This arrangement can carry out the rating test of pure direct motor drive test and electric machine controller MC22.
5, hybrid power test:
(1) tandem: disconnect the shaft coupling 16 between motor 4 and the sensor 5, Engine ECU controller ETC19 control Engine ECU 14 makes power by engine 1 output, be delivered to motor 4 through variator 2 and sensor 3, electric machine controller MC22 control motor 4 is operated in generating state, control rectification adverser 11 simultaneously and be operated in inverter mode, motor 4 changes into electric energy with mechanical energy, stores in the battery 13 through rectification adverser 11.Provide electric power by battery 13, electric machine controller MC27 control rectification adverser 12 is operated in rectification state, controls motor 9 simultaneously and is operated in motoring condition, and electric energy is changed into mechanical energy output, is delivered to dynamometer machine 6 through inertia dish 8 and detent 7.This arrangement can carry out the serial mixed power performance test, and the rating test of integrated control system under the serial mixed power pattern to being made up of Engine ECU controller ETC19, electric machine controller MC22, torque converter controller TCU20, battery management unit BCM23, electric machine controller MC27.
(2) parallel: disconnect the shaft coupling 16 between dynamometer machine 6 and the detent 7, disconnection battery 13 is connected with circuit between the rectification adverser 12, and power is provided separately by engine 1 or motor 4.When engine 1 provides power, Engine ECU controller ETC19 control Engine ECU 14 makes engine output power, the required torque of torque converter controller TCU20 control variator 2 output tests, power is through variator 2, sensor 3, motor 4 and sensor 5, be delivered to dynamometer machine 6, electric machine controller MC22 control motor 4 makes it be in generating state, controls rectification adverser 11 simultaneously and is operated in inverter mode, is 13 chargings of battery-super electric capacity; When motor 4 provides power, electric machine controller MC22 control motor 4 is operated in motoring condition, and control rectification adverser 11 is operated in rectification state, provide electric power by battery 13, motor 4 changes into mechanical energy output with electric energy, outputs to dynamometer machine 6 through transmission shaft, at this moment, Engine ECU controller ETC19 control Engine ECU 14 makes engine 1 be in off position, and torque converter controller TCU20 control variator is in neutral position, and cut-out variator 2 is connected with engine 1.This arrangement can carry out parallel type hybrid dynamic automobile performance test and the rating test of integrated control system under the parallel type hybrid dynamic pattern to being made up of Engine ECU controller ETC19, torque converter controller TCU20, electric machine controller MC22 and battery management unit BCM23.
(3) series parallel type: do not disconnect shaft coupling 16, control, make test unit be operated in the series-parallel connection state by integrated control system 18.When Engine ECU controller ETC19 control Engine ECU 14 makes engine 1 outputting power, the required torque of torque converter controller TCU20 control variator 2 outputs, electric machine controller MC22 control motor 4 is operated in generating state, and control rectification adverser 11 is operated in inverter mode, the power storage that motor 4 is transformed is in battery 13, electric machine controller MC27 control motor 9 is operated in generating state, controls inversion rectifier 12 simultaneously and is operated in inverter mode, is battery 13 chargings; When Engine ECU controller ETC19 control Engine ECU 14 makes engine be in off position, torque converter controller TCU20 control variator 2 is in neutral position, cut-out is connected with engine 1, provide electric power by battery-super electric capacity 13, electric machine controller MC27 control rectification adverser 12 is operated in rectification state, control motor 9 simultaneously and be operated in motoring condition, motor 9 changes into mechanical energy with electric energy and is delivered to output shaft, electric machine controller MC22 control rectification adverser 11 is operated in inverter mode, control motor 4 is operated in generating state, and the mechanical energy on the transmission shaft is changed into power storage in battery-super electric capacity 13.This scheme can be carried out the performance test of series parallel hybrid power automobile and to Engine ECU controller ETC19, torque converter controller TCU20, electric machine controller MC22, battery management unit BCM23, Dynamometer Control device DYM25 and the rating test of electric machine controller MC27 under the series parallel hybrid power pattern.
(4) combined type: do not disconnect shaft coupling 16, when Engine ECU controller ETC19 control Engine ECU 14 makes engine 1 outputting power, the rotating speed that torque converter controller TCU20 control variator 2 output tests need, according to the test needs, electric machine controller MC22 can control motor 4 and be operated in generating state or motoring condition, control rectification adverser 11 simultaneously and be operated in inverter mode or rectification state, electric machine controller MC27 control motor 9 is operated in generating state or motoring condition, controls rectification adverser 12 simultaneously and is operated in inverter mode or rectification state; When power was provided by motor 4, Engine ECU controller ETC19 control Engine ECU 14 made engine 1 be in off position, and torque converter controller TCU20 control variator is in neutral position, and cut-out is connected with engine 1, and motor 9 is in generating state; In like manner, when power was provided by motor 9, motor 4 was in generating state.This scheme can be carried out the performance test and the rating test of integrated control system under the combined type hybrid mode to being made up of Engine ECU controller ETC19, torque converter controller TCU20, electric machine controller MC22, battery management unit BCM23, Dynamometer Control device DYM25, electric machine controller MC27 of combined type hybrid vehicle.
6, braking energy recovery test: the shaft coupling 16 between open slew device 2 and the sensor 3, motor 4 is as motor, according to the different tests requirement, 4 output constant torque or the time dependent torques of electric machine controller MC22 may command motor, big or small replaceable different inertia dish 8 according to simulation different vehicle inertia, when detent 7 begins to brake, electric machine controller MC27 control motor 9 is operated in the generator state, rectification adverser 12 is operated in inverter state, inertia energy when motor 9 will be braked changes into electric energy, store in the battery 13, realize recovery, when detent 7 damping force increase to when making transmission shaft be tending towards locking braking energy, brake controller ABS26 work, control brake device 7 reduces damping force, prevents the transmission shaft locking, has increased to recover energy.
7, integrated control system is formed and rating test: by the control system that arbitrarily individual controller in the integrated control system 18 is formed process of the test is controlled.All controllers all are connected on the CAN bus 17, CAN bus 17 is connected to calibration system 29, calibration system is monitored the significant variable data in the integrated control system 18 middle controller operational processs in real time, adjusting the optimal control parameter makes whole integrated control system 18 be complementary optimization Test result with controlled test-bed.
8, battery-super electric capacity: super capacitor and battery are connected in parallel, and super capacitor can provide moment high-power and recovery brake energy, plays important power-balance effect.As the engine accessory power supply, when doing the hybrid power test, reduce consumption, the raising engine peak power of fuel oil significantly and reduce noxious gas emission.Super capacitor can store the energy of recovery fast, and energy snap-out release energy, when quickening and start; by the discharge of battery management unit BCM23 control super capacitor, the high-power of moment is provided, avoid battery to discharge the high-power infringement that battery is caused of moment; the protection battery, extending battery life.

Claims (10)

1. multi-energy hybrid power comprehensive test device, comprise engine (1), torque converter (2), sensor (3), motor (4,9), sensor (5), dynamometer machine (6), detent (7), inertia dish (8), sensor (10), two rectification adversers (11,12), battery-super electric capacity (13), Engine ECU (14), and by Engine ECU controller ETC (19), torque converter controller TCU (20), three sensor digital to analog converter DA (21,24,28), two electric machine controller MC (22,27), battery management unit BCM (23), Dynamometer Control device DYM (25), brake controller ABS (26), the integrated control system (18) that CAN bus (17) is formed;
It is characterized in that: engine (1), torque converter (2), sensor (3), motor (4), sensor (5), dynamometer machine (6), detent (7), inertia dish (8), motor (9) and sensor (10) are coaxial successively by shaft coupling (16) mechanical connection, and are connected with transmission shaft (15);
Wherein, motor (4) is connected with rectification adverser (11) circuit, rectification adverser (11) is connected with battery-super electric capacity (13) circuit, battery and super capacitor are connected in parallel, motor (9) is connected with rectification adverser (12) circuit, rectification adverser (12) is connected with battery-super electric capacity (13) circuit, Engine ECU controller ETC (19) is connected with Engine ECU (14) circuit, gearbox controller TCU (20) is connected with variator (2) circuit, sensor digital to analog converter DA (21) is connected with sensor (3) circuit, electric machine controller MC (22) is connected with rectification adverser (11) circuit, battery management unit BCM (23) is connected with battery-super electric capacity (13) circuit, sensor digital to analog converter DA (24) is connected with sensor (5) circuit, Dynamometer Control device DYM (25) is connected with dynamometer machine (6) circuit, brake controller ABS (26) is connected with detent (7) circuit, electric machine controller MC (27) is connected with rectification adverser (12) circuit, sensor digital to analog converter DA (28) is connected Engine ECU controller ETC (19) with sensor (10) circuit, torque converter controller TCU (20), sensor digital to analog converter DA (21), electric machine controller MC (22), battery management unit BCM (23), sensor digital to analog converter DA (24), Dynamometer Control device DYM (25), brake controller ABS (26), electric machine controller MC (27) is connected with CAN bus (17) circuit with sensor digital to analog converter DA (28).
Also be provided with the calibration system (29) that is connected with integrated control system (18) circuit by CAN bus (17), this calibration system is for having real-time demonstration test figure, and by adjust, the optimal control parameter is complementary integrated control system and multipotency driving source assembly, improves the PC of test findings function.
2. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Disconnect the shaft coupling (16) between engine (1) and the variator (2), Engine ECU (14) is connected with engine (1), Engine ECU controller ETC (19) links to each other with Engine ECU (14) and is connected on the CAN bus (17), communicate by letter with calibration system (29), become the rating test device of engine performance test and Engine ECU controller ETC (19).
3. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Disconnect the shaft coupling (16) between sensor (3) and the motor (4), the torque of engine (1) output is delivered on the output shaft through variator (2), sensor (3) is measured the torque rotary speed on the transmission shaft, gearbox controller TCU (20) is connected with variator (2), becomes the rating test device of transmission performance test and gearbox controller TCU (20).
4. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Disconnect the shaft coupling (16) between sensor (3) and the motor (4), disconnect the shaft coupling between dynamometer machine (6) and the detent (7), electric machine controller MC (22) is connected with rectification adverser (11) with motor (4), battery-super electric capacity (13) is connected with rectification adverser (11), becomes motor properties test and to the rating test device of electric machine controller MC (22).
5. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Shaft coupling (16) between open slew device (2) and the sensor (3), disconnect the shaft coupling (16) between inertia dish (8) and the motor (9), electric machine controller MC (22) is connected with rectification adverser (11) with motor (4), battery-super electric capacity (13) is connected with rectification adverser (11), for motor (4) provides electric power, become the rating test device of pure direct motor drive test and electric machine controller MC (22).
6. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Disconnect the shaft coupling (16) between motor (4) and the sensor (5), Engine ECU controller ETC (19) control Engine ECU (14) makes power be exported by engine (1), be delivered to motor (4) through variator (2) and sensor (3), electric machine controller MC (22) control motor (4) is operated in generating state, control rectification adverser (11) simultaneously and be operated in inverter mode, motor (4) changes into electric energy with mechanical energy, stores in the battery (13) through rectification adverser (11);
Provide electric power by battery (13), electric machine controller MC (27) control rectification adverser (12) is operated in rectification state, control motor (9) simultaneously and be operated in motoring condition, electric energy is changed into mechanical energy output, be delivered to dynamometer machine (6) through inertia dish (8) and detent (7);
Become serial mixed power performance test and the rating test device of integrated control system under the serial mixed power pattern to forming by Engine ECU controller ETC (19), electric machine controller MC (22), torque converter controller TCU (20), battery management unit BCM (23), electric machine controller MC (27).
7. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Disconnect the shaft coupling (16) between dynamometer machine (6) and the detent (7), disconnection battery (13) is connected with circuit between the rectification adverser (12), and power is provided separately by engine (1) or motor (4);
When engine (1) when power is provided, Engine ECU controller ETC (19) control Engine ECU (14) makes engine output power, the required torque of torque converter controller TCU (20) control variator (2) output test, power is through variator (2), sensor (3), motor (4) and sensor (5), be delivered to dynamometer machine (6), electric machine controller MC (22) control motor (4) makes it be in generating state, control rectification adverser (11) simultaneously and be operated in inverter mode, be battery-super electric capacity (13) charging;
When motor (4) when power is provided, electric machine controller MC (22) control motor (4) is operated in motoring condition, and control rectification adverser (11) is operated in rectification state, provide electric power by battery (13), motor (4) changes into mechanical energy output with electric energy, output to dynamometer machine (6) through transmission shaft, at this moment, Engine ECU controller ETC (19) control Engine ECU (14) makes engine (1) be in off position, torque converter controller TCU (20) control variator is in neutral position, and cut-out variator (2) is connected with engine (1);
Become parallel type hybrid dynamic automobile performance test and the rating test device of integrated control system under the parallel type hybrid dynamic pattern to forming by Engine ECU controller ETC (19), torque converter controller TCU (20), electric machine controller MC (22) and battery management unit BCM (23).
8. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Do not disconnect each shaft coupling, control, make test unit be operated in the series-parallel connection state by integrated control system (18);
When Engine ECU controller ETC (19) control Engine ECU (14) makes engine (1) outputting power, torque converter controller TCU (20) control variator (2) is exported required torque, electric machine controller MC (22) control motor (4) is operated in generating state, and control rectification adverser (11) is operated in inverter mode, the power storage that motor (4) is transformed arrives in the battery (13), electric machine controller MC (27) control motor (9) is operated in generating state, control inversion rectifier (12) simultaneously and be operated in inverter mode, be battery (13) charging;
When Engine ECU controller ETC (19) control Engine ECU (14) makes engine be in off position, torque converter controller TCU (20) control variator (2) is in neutral position, cut-out is connected with engine (1), provide electric power by battery-super electric capacity (13), electric machine controller MC (27) control rectification adverser (12) is operated in rectification state, control motor (9) simultaneously and be operated in motoring condition, motor (9) changes into mechanical energy with electric energy and is delivered to output shaft, electric machine controller MC (22) control rectification adverser (11) is operated in inverter mode, control motor (4) is operated in generating state, and the mechanical energy on the transmission shaft is changed into power storage in battery-super electric capacity (13);
Become the performance test of series parallel hybrid power automobile and to Engine ECU controller ETC (19), torque converter controller TCU (20), electric machine controller MC (22), battery management unit BCM (23), Dynamometer Control device DYM (25) and the rating test device of electric machine controller MC (27) under the series parallel hybrid power pattern.
9. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Do not disconnect each shaft coupling (16);
When Engine ECU controller ETC (19) control Engine ECU (14) makes engine (1) outputting power, the rotating speed that torque converter controller TCU (20) control variator (2) output test needs, make electric machine controller MC (22) control motor (4) be operated in generating state or motoring condition, control rectification adverser (11) simultaneously and be operated in inverter mode or rectification state, electric machine controller MC (27) control motor (9) is operated in generating state or motoring condition, controls rectification adverser (12) simultaneously and is operated in inverter mode or rectification state;
When power by motor (4) when providing, Engine ECU controller ETC (19) control Engine ECU (14) makes engine (1) be in off position, torque converter controller TCU (20) control variator is in neutral position, and cut-out is connected with engine (1), and motor (9) is in generating state;
In like manner, when power by motor (9) when providing, motor (4) is in generating state;
Become the performance test and the rating test device of integrated control system under the combined type hybrid mode of combined type hybrid vehicle to forming by Engine ECU controller ETC (19), torque converter controller TCU (20), electric machine controller MC (22), battery management unit BCM (23), Dynamometer Control device DYM (25), electric machine controller MC (27).
10. multi-energy hybrid power comprehensive test device as claimed in claim 1 is characterized in that:
Shaft coupling (16) between open slew device (2) and the sensor (3), motor (4) is as motor, according to the different tests requirement, electric machine controller MC (22) may command motor (4) output constant torque or time dependent torque, and the size according to simulation different vehicle inertia is changed different inertia dishes (8), becomes braking energy recovery test device.
CN2010201959003U 2010-05-14 2010-05-14 Multi-energy hybrid integrated experiment device Expired - Lifetime CN201680967U (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102650664A (en) * 2011-08-30 2012-08-29 广西南宁金络资讯科技有限公司 Self-adaption open energy source system experiment platform
CN103711169A (en) * 2013-08-20 2014-04-09 浙江大学 Automatic idling control method for hybrid excavator
CN106257260A (en) * 2016-07-01 2016-12-28 中国北方车辆研究所 A kind of electro-motive vehicle gear power stream universaling analysis method

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102650664A (en) * 2011-08-30 2012-08-29 广西南宁金络资讯科技有限公司 Self-adaption open energy source system experiment platform
CN103711169A (en) * 2013-08-20 2014-04-09 浙江大学 Automatic idling control method for hybrid excavator
CN103711169B (en) * 2013-08-20 2016-02-03 浙江大学 Hybrid excavator automatic idling control method
CN106257260A (en) * 2016-07-01 2016-12-28 中国北方车辆研究所 A kind of electro-motive vehicle gear power stream universaling analysis method
CN106257260B (en) * 2016-07-01 2020-01-17 中国北方车辆研究所 Analysis method for power circulation of speed change mechanism of electrically driven vehicle

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