MathWorks Inc powertrain blocksettm

Figure 4. Schematic of a series-parallel split hybrid <t>powertrain.</t>

Powertrain Blocksettm, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 92/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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series hybrid electric powertrain architecture (MathWorks Inc)

MathWorks Inc series hybrid electric powertrain architecture

Figure 5. The test platform for a series hybrid electric tractor with a dual-motor-independent- driven <t>powertrain:</t> (a) structural scheme of the series hybrid electric tractor of the test platform; (b) photographs of the reconﬁguration test platform. (1) battery pack; (2) communication converter; (3) operating console; (4) laptop; (5) control system of the drive motor 1; (6) control system of the drive motor 2; (7) right load motor; (8) right raising speed gearbox; (9) drive axle; (10) left raising speed gearbox; (11) left load motor; (12) generator control system; (13) generator; (14) exhaust pipe; (15) grid-connected inverter; (16) charging pile; (17) drive motor 2; (18) drive motor 1; (19) PTO motor; (20) lead–acid battery; (21) engine controller; (22) diesel engine. Note: torque-speed sensors are inside of the yellow covers.

Series Hybrid Electric Powertrain Architecture, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 96/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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simulink powertrain toolbox (MathWorks Inc)

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Fig. 1. Power ﬂow of a hybrid <t>powertrain</t> system.

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Image Search Results

Figure 4. Schematic of a series-parallel split hybrid powertrain.

Journal: Vehicles

Article Title: Design of a Hybrid Electric Vehicle Powertrain for Performance Optimization Considering Various Powertrain Components and Configurations

doi: 10.3390/vehicles3010002

Figure Lengend Snippet: Figure 4. Schematic of a series-parallel split hybrid powertrain.

Article Snippet: MATLAB/Simulink, specifically the Powertrain BlocksetTM, was utilized as the primary tool in the development of the powertrain model to explore various architectures consisting of different components.

Techniques:

Figure 10. Selected vehicle powertrain conﬁgurations and components.

Journal: Vehicles

Article Title: Design of a Hybrid Electric Vehicle Powertrain for Performance Optimization Considering Various Powertrain Components and Configurations

doi: 10.3390/vehicles3010002

Figure Lengend Snippet: Figure 10. Selected vehicle powertrain conﬁgurations and components.

Techniques:

Figure 5. The test platform for a series hybrid electric tractor with a dual-motor-independent- driven powertrain: (a) structural scheme of the series hybrid electric tractor of the test platform; (b) photographs of the reconﬁguration test platform. (1) battery pack; (2) communication converter; (3) operating console; (4) laptop; (5) control system of the drive motor 1; (6) control system of the drive motor 2; (7) right load motor; (8) right raising speed gearbox; (9) drive axle; (10) left raising speed gearbox; (11) left load motor; (12) generator control system; (13) generator; (14) exhaust pipe; (15) grid-connected inverter; (16) charging pile; (17) drive motor 2; (18) drive motor 1; (19) PTO motor; (20) lead–acid battery; (21) engine controller; (22) diesel engine. Note: torque-speed sensors are inside of the yellow covers.

Journal: Applied Sciences

Article Title: Design and Verification of a Modular Reconfigurable Test Platform for Electric Tractors

doi: 10.3390/app11041881

Figure Lengend Snippet: Figure 5. The test platform for a series hybrid electric tractor with a dual-motor-independent- driven powertrain: (a) structural scheme of the series hybrid electric tractor of the test platform; (b) photographs of the reconﬁguration test platform. (1) battery pack; (2) communication converter; (3) operating console; (4) laptop; (5) control system of the drive motor 1; (6) control system of the drive motor 2; (7) right load motor; (8) right raising speed gearbox; (9) drive axle; (10) left raising speed gearbox; (11) left load motor; (12) generator control system; (13) generator; (14) exhaust pipe; (15) grid-connected inverter; (16) charging pile; (17) drive motor 2; (18) drive motor 1; (19) PTO motor; (20) lead–acid battery; (21) engine controller; (22) diesel engine. Note: torque-speed sensors are inside of the yellow covers.

Article Snippet: As mentioned in Section 3.2, it is easy to realize reconfigurable control; we need only design corresponding logical control strategies based on the series hybrid electric powertrain architecture in Simulink and implement those strategies following the steps in Figure 4.

Techniques: Battery, Control

Figure 6. The control model framework of the series hybrid powertrain used in electric tractors.

Journal: Applied Sciences

Article Title: Design and Verification of a Modular Reconfigurable Test Platform for Electric Tractors

doi: 10.3390/app11041881

Figure Lengend Snippet: Figure 6. The control model framework of the series hybrid powertrain used in electric tractors.

Techniques: Control

Fig. 1. Power ﬂow of a hybrid powertrain system.

Journal: IEEE Transactions on Neural Networks and Learning Systems

Article Title: Knowledge Implementation and Transfer With an Adaptive Learning Network for Real-Time Power Management of the Plug-in Hybrid Vehicle

doi: 10.1109/tnnls.2021.3093429

Figure Lengend Snippet: Fig. 1. Power ﬂow of a hybrid powertrain system.

Article Snippet: The vehicle is modeled using the Simulink Powertrain Toolbox based on the dynamometer data.

Techniques:

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