CN113381494A - Self-generating system for travelling crane - Google Patents

Abstract

The invention provides a driving self-generating system, which relates to the technical field of vehicles and specifically comprises a driving power take-off device, a generator and a power converter, wherein the driving power take-off device comprises an engine and a transmission system, and an output shaft of the engine is in transmission connection with an input shaft of the transmission system; the generator comprises a rotor assembly, a first stator assembly and a second stator assembly, an input shaft of the rotor assembly is in transmission connection with an output shaft of the transmission system, and the first stator assembly and the second stator assembly are both arranged on the radial outer side of the rotor assembly and are axially arranged; the power converter comprises a first power conversion circuit and a second power conversion circuit, the first power conversion circuit is electrically connected with the first stator assembly, and the second power conversion circuit is electrically connected with the second stator assembly. The generator with the single rotor and the double stators which are axially distributed is connected with two power supply conversion circuits to supply power to the traveling load.

Description

Self-generating system for travelling crane

Technical Field

The invention relates to the technical field of vehicles, in particular to a driving self-generating system.

Background

A running self-generating system in the vehicle can provide sufficient and stable direct current and alternating current power supplies for vehicle-mounted equipment by being provided with an engine power take-off device, a generator and a power electronic converter. At present, a driving self-generating system is mostly applied to special vehicles and supplies energy to equipment such as computers, communication equipment, sensors and the like. With the continuous progress of the technology, some civilian large-scale vehicles such as emergency rescue and disaster relief vehicles, temporary communication auxiliary vehicles, live broadcast vehicles, motor homes and other vehicle types with more electrical equipment also start to be loaded with the driving self-generating system.

In the prior art, the installation space of a general driving self-generating system is narrow, and especially when the radial installation space of a generator is limited, a left symmetrical generator system and a right symmetrical generator system are sometimes adopted for generating electricity in order to meet the requirement of large generating power. However, both systems are less costly and less complex than a single generator system. However, because a single set of system has no redundancy or backup in the process of driving power generation, if a single point fault (such as winding short circuit, open circuit, power electronic converter element damage and the like) occurs at any point of the system, the system cannot operate.

Disclosure of Invention

The present invention is directed to solving at least one of the above problems to some extent.

Therefore, the invention provides a driving self-generating system which comprises a driving power take-off device, a generator and a power converter, wherein the driving power take-off device comprises an engine and a transmission system, and an output shaft of the engine is in transmission connection with an input shaft of the transmission system; the generator comprises a rotor assembly, a first stator assembly and a second stator assembly, an input shaft of the rotor assembly is in transmission connection with an output shaft of the transmission system, and the first stator assembly and the second stator assembly are both arranged on the radial outer side of the rotor assembly and are axially arranged; the power converter comprises a first power conversion circuit and a second power conversion circuit, the first power conversion circuit is electrically connected with the first stator assembly, and the second power conversion circuit is electrically connected with the second stator assembly.

Optionally, the generator further includes a casing 10, and the rotor assembly 20, the first stator assembly 30 and the second stator assembly 40 are disposed in the casing 10.

Optionally, the first stator assembly and the second stator assembly are coaxially disposed relative to the rotor assembly and symmetrically disposed at two ends of the rotor assembly.

Optionally, the first stator assembly and the second stator assembly are configured and arranged the same as the winding.

Optionally, the first power conversion circuit includes a first rectifier, a first DC/DC module, and a first inverter electrically connected in sequence, an input end of the first rectifier is electrically connected to an output end of the first stator assembly, and an output end of the first inverter is adapted to be connected to a driving load; the second power conversion circuit comprises a second rectifier, a second DC/DC module and a second inverter which are electrically connected in sequence, the input end of the second rectifier is electrically connected with the output end of the second stator assembly, and the output end of the second inverter is suitable for being connected with a driving load.

Optionally, the first power conversion circuit further includes a first auxiliary DC/DC module, an input end of the first auxiliary DC/DC module is electrically connected to the first rectifier, and an output end of the first auxiliary DC/DC module is electrically connected to the second DC/DC module and an input end of the second inverter, respectively.

Optionally, the second power conversion circuit further includes a second auxiliary DC/DC module, an input end of the second auxiliary DC/DC module is electrically connected to the second rectifier, and an output end of the second auxiliary DC/DC module is electrically connected to the first DC/DC module and the input end of the first inverter, respectively.

Optionally, the power converter further includes a backup power source, and the backup power source is respectively connected to the first DC/DC module, the first inverter, the second DC/DC module, and the second inverter to provide backup power.

Optionally, the system further comprises a sensing monitoring device and a fault monitoring unit which are connected with each other, wherein the sensing monitoring device is suitable for monitoring the generator and the power converter and transmitting monitored signals to the fault monitoring unit, and the fault monitoring unit is suitable for performing operation according to the signals and regulating and controlling the system.

Optionally, the sensing and monitoring device includes a voltage sensor, a current sensor and a temperature sensor, which are respectively electrically connected to the fault monitoring unit, and the voltage sensor, the current sensor and the temperature sensor are respectively adapted to monitor the voltage, the current and the temperature of the generator.

Compared with the prior art, the driving self-generating system provided by the invention has the following technical effects:

the driving self-generating system provided by the invention is in transmission connection with an engine of a driving through a transmission system to take power and generate power through the arranged generator with the single rotor and the double stators which are axially distributed, and outputs applicable and reliable electric energy for a driving load or a vehicle-mounted battery through the first power supply conversion circuit and the second power supply conversion circuit which are connected with the two power supply converters. Wherein, through setting up the generator to the structure of the single rotor double stator of axial distribution for just can realize driving high-power electricity generation in narrow and small installation space, especially when generator radial installation space is limited, through all set up first stator subassembly and second stator module in the radial outside of rotor subassembly and coaxial arranging, do not occupy unnecessary generator radial installation space, the installation space has been utilized more rationally, make the maximize of realizing generating power in limited installation space, and the cost has been saved to the single set generator. Meanwhile, the first power supply conversion circuit and the second power supply conversion circuit are respectively connected with the first stator assembly and the second stator assembly, so that when the high-power generation of the single set of the driving power take-off device and the generator is realized, the system can still continue to normally generate power through the other stator assembly if a circuit or an electronic component in one stator assembly or one power supply conversion circuit is damaged, the reliability of the system is improved, the driving self-generating system of the single set of the driving power take-off device and the generator has redundancy and fault tolerance, and the safety and reliability of the system operation are ensured. Moreover, this system can carry out grouping optimal design according to actual driving load through the first stator subassembly and the second stator subassembly that set up, can be through adjusting the winding configuration or the structural design who sets up first stator subassembly and second stator subassembly respectively promptly to make and carry out special suitability power supply corresponding different driving loads, and then promoted the energy efficiency ratio of system.

Drawings

FIG. 1 is a schematic diagram of a generator according to an embodiment of the present invention;

FIG. 2 is a block diagram of the power generation system during driving according to the embodiment of the present invention;

FIG. 3 is a block diagram of the operation principle of the power generation system during driving according to the embodiment of the present invention;

fig. 4 is a flowchart illustrating the operation of the sensing and monitoring device and the fault monitoring unit according to the embodiment of the present invention.

Description of reference numerals:

10-a machine casing, 20-a rotor assembly, 30-a first stator assembly, 40-a second stator assembly, 50-a drive shaft of a generator.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

It should be noted that in the description of the present disclosure, the directions or positional relationships indicated by "upper", "lower", "left", "right", "top", "bottom", "front", "rear", "inner" and "outer" are used as the directions or positional relationships indicated in the drawings, which are only for convenience of describing the present disclosure, but do not indicate or imply that the device referred to must have a specific direction, be configured and operated in a specific direction, and thus, should not be interpreted as limiting the scope of the present disclosure.

The terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature.

Moreover, although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims. It should be understood that features described in different dependent claims and herein may be combined in ways different from those described in the original claims. It is also to be understood that features described in connection with individual embodiments may be used in other described embodiments.

The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

As shown in fig. 1 and fig. 2, an embodiment of the present invention provides a driving self-generating system, including a driving power take-off, a generator and a power converter, wherein the driving power take-off includes an engine and a transmission system, and an output shaft of the engine is in transmission connection with an input shaft of the transmission system; the generator comprises a rotor assembly 20, a first stator assembly 30 and a second stator assembly 40, wherein an input shaft of the rotor assembly 20 is in transmission connection with an output shaft of the transmission system, and the first stator assembly 30 and the second stator assembly 40 are both arranged on the radial outer side of the rotor assembly 20 and are arranged axially; the power converter includes a first power conversion circuit electrically connected to the first stator assembly 30 and a second power conversion circuit electrically connected to the second stator assembly 40.

Specifically, the generator provided in this embodiment further includes a casing 10, and the rotor assembly 20, the first stator assembly 30 and the second stator assembly 40 are all disposed in the casing 10. The output shaft of the transmission system is in transmission connection with the transmission shaft 50 of the generator, and the transmission shaft 50 of the generator is the input shaft of the rotor assembly 20. In the embodiment, the engine of the travelling crane provides power for the generator to be converted into electric energy, namely the travelling crane is self-generating.

In this embodiment, the traveling crane self-generating system provided by this embodiment is configured such that the generator with axially distributed single rotor and double stators is in transmission connection with the engine of the traveling crane through the transmission system to perform power take-off and power generation, and outputs suitable and reliable electric energy for the traveling crane load through the first power conversion circuit and the second power conversion circuit connected to the two power converters. Wherein, through setting up the generator to the structure that the single rotor double stator that the axial distributes arranges in same casing 10, make just can realize driving high-power electricity generation in narrow and small installation space, especially when generator radial installation space is limited, through all setting up first stator subassembly 30 and second stator subassembly 40 in the radial outside of rotor subassembly 20 and coaxial arranging, do not occupy unnecessary generator radial installation space, installation space has been utilized more rationally, make the maximize of generating power realize in limited installation space, and the cost has been saved to the single set of generator. Meanwhile, the first power supply conversion circuit and the second power supply conversion circuit are respectively connected with the first stator assembly 30 and the second stator assembly 40, so that when the single set of driving power take-off device and the generator realize high-power generation, if a circuit or an electronic component in one stator assembly or one path of power supply conversion circuit is damaged, the system can still continue to normally generate power through the other stator assembly, the reliability of the system is improved, the driving self-generating system of the single set of driving power take-off device and the generator has redundancy and fault tolerance, and the safety and reliability of the system operation are ensured. Moreover, this system can carry out grouping optimal design according to actual driving load through the first stator subassembly 30 and the second stator subassembly 40 that set up, can be through adjusting the winding configuration or the structural design who sets up first stator subassembly 30 and second stator subassembly 40 respectively promptly to make and carry out special suitability power supply corresponding different driving loads, and then promoted the energy efficiency ratio of system.

Alternatively, as shown in fig. 1, the first stator assembly 30 and the second stator assembly 40 provided in this embodiment are coaxially disposed with respect to the rotor assembly 20, and are symmetrically disposed at two ends of the rotor assembly 20.

In this embodiment, through setting up the coaxial symmetry of first stator subassembly 30 and the relative rotor subassembly 20 of second stator subassembly 40, the radial occupation space of generator casing 10 has been saved to the at utmost, simultaneously through setting up the car at the both ends of rotor subassembly 20 with first stator subassembly 30 and second stator subassembly 40, the production of the subassembly of being convenient for, installation and allotment, generate electricity with first stator subassembly 30 and the cooperation of second stator subassembly 40 simultaneously respectively through one set of rotor subassembly 20, the utilization ratio of rotor subassembly 20 is improved, and material and manufacturing cost have been saved simultaneously.

Alternatively, as shown in fig. 1, the first stator assembly 30 and the second stator assembly 40 provided in the present embodiment have the same structure and winding arrangement.

In this embodiment, the first stator assembly 30 and the second stator assembly 40 are set to have the same winding and structure, so that the first stator assembly 30 and the second stator assembly 40 can generate the same power generation amount respectively in cooperation with the rotor assembly 20, and have the same power, that is, when one of the first stator assembly 30 and the second stator assembly 40 fails, the other stator assembly can be replaced at any time, so that the real-time normal operation of the system is ensured, and the butt joint power supply can be performed without adjusting the conversion of other circuits or electronic power modules, so that the reliability and the timeliness of the system are ensured.

Optionally, as shown in fig. 3, the first power conversion circuit provided in this embodiment includes a first rectifier, a first DC/DC module, and a first inverter, which are electrically connected in sequence, an input end of the first rectifier is electrically connected to an output end of the first stator assembly 30, and an output end of the first inverter is adapted to be connected to a driving load.

In the embodiment, the first power conversion circuit is provided as the first rectifier, the first DC/DC module and the first inverter which are connected in this way, and the first rectifier is electrically connected with the first stator assembly 30, so that part of the generated energy of the first stator assembly 30 in the generator can be converted into electric energy suitable for the driving load, and the electric energy can be stably supplied. Specifically, the first rectifier receives three-phase alternating current generated by the first stator assembly 30 in the generator, converts the three-phase alternating current into high-voltage direct current and transmits the high-voltage direct current to the first DC/DC module, the first DC/DC module converts the high-voltage direct current into appropriate direct current and transmits the appropriate direct current to the first inverter, and the first inverter converts the direct current into alternating current suitable for being used by a traveling load. Specifically, the driving load in this embodiment is an alternating current load. The first power conversion circuit is matched with the first stator assembly 30 of the generator in the embodiment to provide stable and reliable electric energy for the driving load, and the power conversion circuit is reasonable in structure and stable in operation.

Optionally, as shown in fig. 3, the second power conversion circuit in this embodiment includes a second rectifier, a second DC/DC module, and a second inverter, which are electrically connected in sequence, an input end of the second rectifier is electrically connected to an output end of the second stator assembly 40, and an output end of the second inverter is adapted to be connected to a traveling load.

In this embodiment, the second power conversion circuit has the same composition and operation principle as the first power conversion circuit, that is, the second rectifier receives the three-phase ac power generated by the second stator assembly 40 in the generator, converts the three-phase ac power into high-voltage DC power and transmits the high-voltage DC power to the second DC/DC module, the second DC/DC module converts the high-voltage DC power into suitable DC power and transmits the suitable DC power to the second inverter, and the second inverter converts the DC power into ac power suitable for the traveling load.

It should be noted that, in this embodiment, the first power conversion circuit and the second power conversion circuit may also be designed to have different compositions, and the above-mentioned purpose can also be achieved, and the driving loads connected to the first power conversion circuit and the second power conversion circuit may be the same or different, that is, the first power conversion circuit and the second power conversion circuit may supply power to the whole driving load through one path, and the second power conversion circuit is used as a backup, and the first power conversion circuit and the second power conversion circuit may also supply power to parts of the whole driving load through the two paths respectively.

Meanwhile, it should be understood that, when the traveling self-power generation system works, the traveling control system can regulate and control the traveling self-power generation system, namely, the traveling control system can respectively regulate and control the first power conversion circuit and the second power conversion circuit so as to meet actual requirements.

Optionally, as shown in fig. 3, the first power conversion circuit provided in this embodiment further includes a first auxiliary DC/DC module, an input end of the first auxiliary DC/DC module is electrically connected to the first rectifier, and an output end of the first auxiliary DC/DC module is electrically connected to the second DC/DC module and an input end of the second inverter, respectively.

In this embodiment, the first auxiliary DC/DC module is disposed in the first power conversion circuit, and the first auxiliary DC/DC module is electrically connected to the second DC/DC module and the second inverter, so that the first power conversion circuit can serve as the second DC/DC module and the second inverter through the first auxiliary DC/DC module, that is, the first power conversion circuit makes a redundant backup for the second power conversion circuit through the first auxiliary DC/DC module, thereby further improving the redundancy and fault tolerance of the vehicle self-power generation system, and further making the overall operation more stable and reliable.

Optionally, as shown in fig. 3, the second power conversion circuit provided in this embodiment further includes a second auxiliary DC/DC module, an input end of the second auxiliary DC/DC module is electrically connected to the second rectifier, and an output end of the second auxiliary DC/DC module is electrically connected to the first DC/DC module and the input end of the first inverter, respectively.

In this embodiment, the second auxiliary DC/DC module acts on the same working principle as the first auxiliary DC/DC module, and through the arrangement of the first auxiliary DC/DC module and the second auxiliary DC/DC module, the mutual redundant backup of the first power conversion circuit and the second power conversion circuit is achieved, so that the reliability of the vehicle power generation system is further improved.

Optionally, as shown in fig. 3, the power converter provided in this embodiment further includes a backup power source, and the backup power source is respectively connected to the first DC/DC module, the first inverter, the second DC/DC module, and the second inverter to provide backup power.

In this embodiment, by providing the backup power supply in the power converter, power can be supplied to the first DC/DC module, the first inverter, the second DC/DC module, and the second inverter, and the backup power supply can be used as a backup control power supply, thereby further ensuring the reliability of the system. Specifically, the backup power supply provided by the present embodiment is a low-voltage dc power supply/battery. Meanwhile, the standby power supply can also comprise a first high-voltage direct-current power supply/battery and a second high-voltage direct-current power supply/battery, the first high-voltage direct-current power supply is connected with the first DC/DC module, the second high-voltage direct-current power supply/battery is connected with the second DC/DC module, the reliability and the redundancy of the system can be further ensured by arranging the first high-voltage direct-current power supply/battery and the second high-voltage direct-current power supply/battery, and the standby power supply can be used as a backup control power supply and simultaneously provides energy storage support for the system and the whole system. Optionally, as shown in fig. 3 and fig. 4, the driving self-power generation system provided in this embodiment further includes a sensing monitoring device and a fault monitoring unit, which are connected to each other, the sensing monitoring device is adapted to monitor the generator and the power converter, and transmit a monitored signal to the fault monitoring unit, and the fault monitoring unit is adapted to perform operation and regulate and control the system according to the signal.

In this embodiment, by setting the sensing monitoring device and the fault monitoring unit, the related working parameters of the generator can be monitored in real time, fault identification is performed through the fault monitoring unit, and the system is regulated and controlled in real time, so that the safety of system operation is further ensured.

Optionally, as shown in fig. 3 and 4, the sensing and monitoring device provided in this embodiment includes a voltage sensor, a current sensor, and a temperature sensor, which are respectively electrically connected to the fault monitoring unit, and the voltage sensor, the current sensor, and the temperature sensor are respectively adapted to monitor the voltage, the current, and the temperature of the generator.

In this embodiment, the input ends of the voltage sensor, the current sensor and the temperature sensor are respectively connected to the generator, and respectively collect the line-line voltage, the line current and the winding temperature value signals of the generator, and transmit the signals to the fault monitoring unit for operation processing, and then regulate and control the power converter, and the system operation is accurately controlled through closed-loop control.

The sensing monitoring device comprises a voltage sensor, a current sensor, a rotating speed sensor, a fault monitoring unit, a fault identification unit and a power supply converter, wherein the voltage sensor is a line-line voltage sensor, the current sensor is a line current sensor, the rotating speed sensor is used for collecting rotating speed of a generator, the rotating speed sensor transmits collected real-time rotating speed numerical signals of the generator to the fault monitoring unit, the fault identification unit reads rotating speed measured values, line-line voltage measured values, line current measured values and winding temperature measured values through the sensors, compares the rotating speed measured values, the line-line voltage measured values, the line current measured values and the winding temperature measured values with a rotating speed, voltage and current reference value database in a system, calculates a voltage-current phase difference and identifies whether the winding temperature is overheated or not, so that system faults are identified, if the system faults exist, alarm information is sent out in time, and the power supply converter is regulated and controlled. Specifically, the output end of the fault monitoring unit is connected with a first DC/DC module, a first inverter, a second DC/DC module and a second inverter of the power converter so as to regulate and control the first DC/DC module, the first inverter, the second DC/DC module and the second inverter in real time. Through the arrangement, the system is ensured to run safely, accurately, stably and reliably.

Specifically, in this embodiment, the sensing and monitoring devices are provided in two sets, that is, the sensing and monitoring devices include two sets of line-line voltage sensors, line current sensors, temperature sensors, and rotation speed sensors, and are respectively connected to the generator.

In addition, as shown in fig. 1 to 4, based on the driving self-generating system, another embodiment of the present invention provides a driving self-generating device, which is arranged on a vehicle, and includes a driving power takeoff, a generator, and a power converter, wherein the driving power takeoff includes an engine and a transmission system, and an output shaft of the engine is in transmission connection with an input shaft of the transmission system; the generator comprises a rotor assembly 20, a first stator assembly 30 and a second stator assembly 40, wherein an input shaft of the rotor assembly 20 is in transmission connection with an output shaft of the transmission system, and the first stator assembly 30 and the second stator assembly 40 are both arranged on the radial outer side of the rotor assembly 20 and are arranged axially; the power converter includes a first power conversion circuit electrically connected to the first stator assembly 30 and a second power conversion circuit electrically connected to the second stator assembly 40.

As shown in fig. 3, the first power conversion circuit provided in this embodiment includes a first rectifier, a first DC/DC module, and a first inverter, which are electrically connected in sequence, wherein an input end of the first rectifier is electrically connected to an output end of the first stator assembly 30, and an output end of the first inverter is adapted to be connected to a driving load. The second power conversion circuit comprises a second rectifier, a second DC/DC module and a second inverter which are electrically connected in sequence, wherein the input end of the second rectifier is electrically connected with the output end of the second stator assembly 40, and the output end of the second inverter is suitable for being connected with a traveling load. Meanwhile, the first power conversion circuit further comprises a first auxiliary DC/DC module, wherein the input end of the first auxiliary DC/DC module is electrically connected with the first rectifier, and the output end of the first auxiliary DC/DC module is electrically connected with the input ends of the second DC/DC module and the second inverter respectively. The second power conversion circuit further comprises a second auxiliary DC/DC module, wherein the input end of the second auxiliary DC/DC module is electrically connected with the second rectifier, and the output end of the second auxiliary DC/DC module is electrically connected with the first DC/DC module and the input end of the first inverter respectively. According to the arrangement, the driving self-generating device is connected with the two power generation lines through the power generator, the two power generation lines are redundant and backup to each other, and better fault tolerance and reliability are achieved.

Meanwhile, the power converter provided by this embodiment further includes a standby power source, and the standby power source is respectively connected to the first DC/DC module, the first inverter, the second DC/DC module, and the second inverter to provide standby power. Specifically, the backup power source is a low voltage dc power source/battery. Meanwhile, the standby power supply can also comprise a first high-voltage direct-current power supply/battery and a second high-voltage direct-current power supply/battery, the first high-voltage direct-current power supply is connected with the first DC/DC module, the second high-voltage direct-current power supply/battery is connected with the second DC/DC module, the reliability and the redundancy of the system can be further ensured by arranging the first high-voltage direct-current power supply/battery and the second high-voltage direct-current power supply/battery, and the standby power supply can be used as a backup control power supply and simultaneously provides energy storage support for the system and the whole system.

As shown in fig. 3 and 4, the driving self-power generation device provided in this embodiment further includes a sensing monitoring device and a fault monitoring unit, which are connected to each other, the sensing monitoring device is adapted to monitor the power generator and the power converter, and transmit a monitored signal to the fault monitoring unit, and the fault monitoring unit is adapted to perform an operation according to the signal and regulate and control the driving self-power generation device.

Specifically, the sensing and monitoring device comprises two sets of line-line voltage sensors, line current sensors and temperature sensors which are respectively electrically connected with the fault monitoring unit, are respectively used for monitoring the voltage, the current and the temperature numerical signals of the two power generation lines, and comprise a rotating speed sensor for monitoring the rotating speed of the generator.

As shown in fig. 4, the working process of the sensing and monitoring device and the fault monitoring unit of the driving self-power generation device provided in this embodiment is as follows:

firstly, starting a self-generating device of the traveling crane, and electrifying and working a sensing monitoring device and a fault monitoring unit, namely, collecting numerical signals of voltage, current and temperature of two paths of generating lines by two sets of line-line voltage sensors, line current sensors and temperature sensors respectively, collecting rotating speed numerical signals of a generator by a rotating speed sensor and transmitting the rotating speed numerical signals to the fault monitoring unit respectively, reading the measured values of the rotating speed sensors, the measured values of the line-line voltage, the measured values of the line current and the measured values of the temperature sensors by the fault monitoring unit respectively, comparing and analyzing the measured values of the rotating speed, the measured values of the voltage and the measured values of the current with a rotating speed-voltage-current reference value database in a system, if the abnormal values exist, detecting the fault, prompting an alarm signal, and simultaneously turning off a corresponding power converter module; in addition, the fault monitoring unit carries out voltage and current phase difference calculation on the read voltage and current measured values, and if the read voltage and current measured values are abnormal, the corresponding instruction and action are made; in addition, the fault monitoring unit reads the temperature value of the temperature sensor and judges whether the temperature is overheated or not, and if so, the fault monitoring unit also makes the corresponding instruction and action. As the arrangement and the design, the self-generating device of the automobile can be ensured to operate safely and stably.

Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. Various changes and modifications may be effected therein by one of ordinary skill in the pertinent art without departing from the spirit and scope of the present disclosure, and these changes and modifications are intended to be within the scope of the present disclosure.

Claims (10)

1. A driving self-generating system is characterized by comprising a driving power take-off device, a generator and a power converter, wherein,

the driving power take-off device comprises an engine and a transmission system, wherein an output shaft of the engine is in transmission connection with an input shaft of the transmission system;

the generator comprises a rotor assembly (20), a first stator assembly (30) and a second stator assembly (40), an input shaft of the rotor assembly (20) is in transmission connection with an output shaft of the transmission system, and the first stator assembly (30) and the second stator assembly (40) are both arranged on the radial outer side of the rotor assembly (20) and are arranged axially;

the power converter comprises a first power conversion circuit and a second power conversion circuit, the first power conversion circuit is electrically connected with the first stator assembly (30), and the second power conversion circuit is electrically connected with the second stator assembly (40).

2. A vehicular autonomous system according to claim 1, characterized in that said generator further comprises a casing (10), said rotor assembly (20), said first stator assembly (30) and said second stator assembly (40) being disposed within said casing (10).

3. A vehicular autonomous system according to claim 2, characterized in that said first stator assembly (30) and said second stator assembly (40) are coaxially arranged with respect to said rotor assembly (20) and symmetrically arranged at both ends of said rotor assembly (20).

4. A vehicular autonomous system according to claim 3, characterized in that the structure and the winding arrangement of the first stator assembly (30) and the second stator assembly (40) are identical.

5. A driving self-generating system according to claim 1, wherein the first power conversion circuit comprises a first rectifier, a first DC/DC module and a first inverter electrically connected in sequence, wherein an input end of the first rectifier is electrically connected with an output end of the first stator assembly (30), and an output end of the first inverter is adapted to be connected with a driving load; the second power conversion circuit comprises a second rectifier, a second DC/DC module and a second inverter which are electrically connected in sequence, the input end of the second rectifier is electrically connected with the output end of the second stator assembly (40), and the output end of the second inverter is suitable for being connected with a travelling load.

6. The vehicle driving self-generating system according to claim 5, wherein the first power conversion circuit further comprises a first auxiliary DC/DC module, an input terminal of the first auxiliary DC/DC module is electrically connected to the first rectifier, and an output terminal of the first auxiliary DC/DC module is electrically connected to the second DC/DC module and an input terminal of the second inverter, respectively.

7. The driving self-power-generation system according to claim 5, wherein the second power conversion circuit further comprises a second auxiliary DC/DC module, an input end of the second auxiliary DC/DC module is electrically connected to the second rectifier, and an output end of the second auxiliary DC/DC module is electrically connected to the first DC/DC module and an input end of the first inverter, respectively.

8. A vehicular power generation system according to claim 5, wherein said power converter further comprises a backup power source connected to said first DC/DC module, said first inverter, said second DC/DC module and said second inverter, respectively, for supplying backup power.

9. A vehicular power generation system according to claim 1, further comprising a sensing and monitoring device and a fault monitoring unit connected to each other, wherein the sensing and monitoring device is adapted to monitor the power generator and the power converter and transmit the monitored signals to the fault monitoring unit, and the fault monitoring unit is adapted to perform operation and control on the system according to the signals.

10. A vehicular autonomous electrical system according to claim 9 wherein the sensing and monitoring device comprises a voltage sensor, a current sensor and a temperature sensor electrically connected to the fault monitoring unit, respectively, the voltage sensor, the current sensor and the temperature sensor being adapted to monitor the voltage, the current and the temperature of the generator respectively.

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