RU2638219C1 - Hybrid vehicle with asynchronous engine - Google Patents

Abstract

FIELD: transportation.

SUBSTANCE: hybrid vehicle contains an on-board power source, a power storage device, a storage device power converter into three-phase alternating voltage and a wheel electric driving motor. There are also power converters and wheel drives. The power storage device is connected to the on-board power source which contains the batteries connected in series. Each converter contains six transistor switches. The emitters of the first, second and third keys are connected to the collectors of the fourth, fifth and sixth keys and are connected in the first common point connected with the energy storage device. The collectors of the fourth, fifth and sixth keys are connected to the second common point connected to the midpoint between the batteries of the storage device. Each electric drive of the wheels contains an asynchronous motor whose stator windings are connected in a star. The start of the first, second and third windings is connected to the emitter of the second, first and third keys, respectively. The ends of the windings are connected to the power storage device. The key bases are connected to the outputs of the microcontroller unit.

EFFECT: higher vehicle reliability.

1 dwg

Description

The invention relates to vehicles, namely to hybrid vehicles made on the basis of a three-phase asynchronous electric drive.

A drive device for a hybrid vehicle is known [RU 2371329 C1, IPC B60K 6/00 (2007.10), publ. 10.27.2009] containing a rotating electrical device; a power transmission mechanism combining the power generated by the rotating electric device with the power generated by the internal combustion engine and supplying the combined power to the drive shaft, a power control unit controlling the rotating electric device, a casing having a first placement portion used to house the power control unit and a second placement portion used to accommodate at least the rotating electrical device and combined with the first portion m accommodation, and a lid member mounted on the casing and covering an opening of the first accommodation portion. The power control unit comprises a DC-to-AC converter configured in accordance with a rotating electrical device, and a voltage converter configured to generate an input voltage of the DC-to-AC converter.

The drive of a hybrid vehicle becomes inoperative in case of failures of the type: “open circuit of the stator winding of an electric motor” or “failure of the key of the frequency converter”. There is a complete stop of the hybrid vehicle, since the circular rotating field of the working engine after the accident becomes pulsating with zero torque.

Known adopted for the prototype, a hybrid car [RU 2481969 C2, B60L 11/18 (2006.01), Н02К 44/00 (2006.01), Н05Н 1/00 (2006.01), publ. 05/20/2013], containing on-board electrical energy source, electrical energy storage device, electronic converter electric energy converter into three-phase alternating voltage and electric wheel drive connected via signal and control inputs / outputs through the on-board electronic computer with the vehicle control panel. The on-board source of electrical energy contains a pulsed plasma chemical reactor, at the plasma output of which a magnetohydrodynamic generator and a catalytic battery are connected in series with the output voltage and connected to the electrical energy storage device. The electric wheel drive contains an electronic switch for supplying three-phase voltage and a block of asynchronous electric motors for rotating the wheels of the car, the stator windings of which are connected to the output of the electronic converter through the supply of three-phase voltage through an electronic switch, the control input of which is connected to the vehicle control panel via the on-board computer. Asynchronous electric motors for rotating the wheels of a car are made with the possibility of connecting their shafts to the shafts of rotation of the wheels of the car through differential gear or by directly installing the wheels on the shafts of rotation of the asynchronous motors.

In the prototype, a three-phase asynchronous motor is connected to a frequency converter. In this case, in a working three-phase mode, a circular rotating field is formed and three-phase currents with a phase shift of 2π / 3 flow in the motor windings. When the stator winding breaks in the drive motor or the key fails in the drive frequency converter, the circular rotating field of the working motor after the accident becomes pulsating with zero torque, since the process of forming three-phase currents depends on the current flowing in the adjacent phases of the motor. The currents after the accident in two working phases will have the same amplitude with a phase shift π. Therefore, the drive motor becomes completely inoperative.

A hybrid car becomes inoperative in case of failures of the type: “open stator winding of an electric motor or“ key failure of the frequency converter ”, the hybrid car stops completely.

The objective of the invention is to ensure the survivability of a hybrid vehicle when the stator winding of the induction motor breaks or the key of the frequency converter fails.

The proposed hybrid vehicle with an induction motor, as in the prototype, contains an on-board source of electric energy, an electric energy storage device, a converter electric energy converter into a three-phase AC voltage and a wheel drive containing an electric motor, a microcontroller is connected to a control panel, electric motors for wheel rotation the vehicle is made with the possibility of connecting their shafts with shafts of rotation of the wheels of the vehicle through the differential socio transmission.

According to the invention contains n-converters of electrical energy and n-wheel drives, where n = 2, 4, 6, 8, .... An electrical energy storage device is connected to the on-board electrical energy source, which contains storage batteries connected in series with each other. Each electrical energy converter contains six transistor switches. The emitters of the first, second, and third keys, respectively, are connected to the collectors of the fourth, fifth, and sixth keys.

The emitters of the first, second and third keys are connected to the first common point, which is connected with the electric energy storage device. The collectors of the fourth, fifth and sixth keys are connected to a second common point, which is connected with the midpoint between the batteries of the electric energy storage device. Each electric wheel drive contains an asynchronous motor with stator windings, which are connected in the form of a star. The beginning of the first stator winding is connected to the emitter of the second transistor switch. The beginning of the second stator winding is connected to the emitter of the first transistor switch. The beginning of the third stator winding is connected to the emitter of the third transistor switch. The ends of the stator windings are connected to an electrical energy storage device. The key bases are connected to the outputs of the microcontroller unit.

The proposed device provides the formation of three-phase currents in a working three-phase mode, however, the flow of currents in one phase does not depend on two adjacent phases, which means that when a failure occurs in one of the phases in the two remaining phases, two-phase currents with a phase shift of 2π / 3 continue to form.

The field in the gap of induction motors in this case will be elliptical, the active engine power drops by 33%, which does not ensure uniform rotation of the motor shaft, but provides a limited functionality with the formation of the survivability property of the vehicle drive for differential transmission when the stator winding breaks the induction motor or the key fails frequency converter.

In FIG. 1 shows a diagram of a hybrid vehicle with one drive and differential transmission on two drive wheels.

A hybrid vehicle with an induction motor (Fig. 1) contains an on-board source of electric energy 1 (IEE), an electric energy storage device 2 (NEE), n-converters of electric energy 3 (PEE1), ..., 3n (PEEn) and n-electric drives wheels 4 (PK1), ..., 4n (PKn), where n = 2, 4, 6, 8, .... An electrical energy storage device 2 (NEE) is connected to the on-board source of electrical energy 1 (IEE).

The electric energy storage device 2 (NEE) contains batteries connected in series.

Each electric energy converter 3 (PEE1), ..., 3n (PEEn) contains six transistor switches 3.1, ..., 3.6. The emitters of the first 3.1, second 3.2, and third 3.3 keys, respectively, are connected to the collectors of the fourth 3.4, fifth 3.5, and sixth 3.6. keys.

The emitters of the first 3.1, second 3.2 and third 3.3 keys are connected to the first common point, which is connected to the electric energy storage device 2 (NEE). Collectors of the fourth 3.4, fifth 3.5 and sixth 3.6. keys connected to the second common point, which is connected with the midpoint 5 between the batteries of the electric energy storage device 2 (NEE). Each electric wheel drive 4 (PK1), ..., 4n (PKn) contains an induction motor 6 with stator windings 6.1, 6.2, 6.3, which are connected according to a star circuit. The rotation shaft 7 of the asynchronous electric motor 6 (HELL) is connected to the shaft of rotation of the wheels of the vehicle through a differential gear 8.

The beginning of the stator winding 6.1 is connected to the emitter of the second 3.2 transistor switch. The beginning of the stator winding 6.2 is connected to the emitter of the first 3.1 transistor switch. The beginning of the stator winding 6.3 is connected to the emitter of the third 3.3 transistor switch. The ends of the stator windings 6.1, 6.2, 6.3 are connected to the electric energy storage device 2 (NEE).

Key databases 3.1, ..., 3.6 are connected to the outputs of the microcontroller unit 9 (MK), which is connected to the control panel 10 (PU).

As an on-board source of electrical energy 1 (IEE), BoschS4 Silver can be used, containing a series-connected internal combustion engine (or diesel engine), a rectifier and a generator.

In the electric energy storage device 2 (NEE), S46B24R “ATLAS” batteries can be used. Remote control 10 (PU) is a remote control type 8974552030 TOYOTA, consisting of a monitor, steering wheel, pedals.

A hybrid vehicle with an induction motor operates as follows.

The driver of the vehicle from the control panel 10 (PU) with a removable ignition key supplies the microcontroller 9 (MK) with a signal to turn on the on-board power source 1 (IEE) of the hybrid vehicle's power supply. The process of movement begins. At the same time, the microcontroller 9 (MK) supplies a control signal to the electric energy converters 3 (PEE1), ..., 3n (PEEn) for connecting the electric energy storage device 2 (NEE) to the batteries and converting the direct voltage of the indicated batteries to an alternating three-phase voltage. Next, the driver includes the direction of movement of the vehicle lever "back and forth". In this case, the microcontroller 9 (MK) through the control panel 10 (PU) gives a signal to switch the stator windings 6.1, 6.2, 6.3 of the asynchronous motors 6 in the selected direction of rotation of the wheel drives 4 (PC1), ..., 4n (PCn). Then, the driver sets the vehicle’s speed pedal through the microcontroller 9 (MK) to the electric energy converters 3 (PEE1), ..., 3n (PEEn) the frequency of the three-phase voltage proportional to the speed of rotation of the wheel drives 4 (PK1), ..., 4n (PCn). In this case, a three-phase voltage of a given frequency of electric energy converters 3 (PEE1), ..., 3n (PEEn) is supplied simultaneously to the stator windings of motors 6.1, 6.2, 6.3, front and / or rear wheel drives 4 (PK1), ..., 4n (PCn) depending on the driving mode chosen by the driver based on the quality of the road and speed limits. The driver presses the brake pedal to issue the microcontroller 9 (MK) through the control panel 10 (PU) commands to the electric energy converters 3 (PEE1), ..., 3n (PEEn) to switch the stator windings of asynchronous motors 6 to reverse movement and to change the voltage frequency proportional to the pressure on the brake pedal. In this case, induction motors 6 switch to a mode of generating electricity, namely, conversion when braking the wheels of the inertia energy of the vehicle into electrical energy. The braking electricity from the windings of induction motors 6.1, 6.2, 6.3 through electric energy converters 3 (PEE1), ..., 3n (PEEn) and electric energy storage 2 (NEE) is returned to recharge its power batteries.

In the event of an accident: a broken phase of the stator winding of the induction motor 6.1, 6.2, 6.3 or a key failure 3.1, ..., 3.6 of the electric power converter 3 (PEE1), ..., 3n (PEEn), a power drop occurs, the speed decreases. Information on reducing current consumption by electric energy converters 3 (PEE1), ..., 3n (PEEn) is received at the control input to microcontroller 9 (MK) and information about the accident and available residual resource on the power of an induction motor appears on the control panel 10 (PU) 6. The speed of movement decreases. The driver either continues to drive taking into account power limitations, or, if the power resource allows, the driver compensates for the loss of power by 33% with a speed pedal.

In the case of starting the vehicle after an unresolved accident, the process of starting the vehicle does not differ from normal operation, taking into account the restrictions on the reduced power of the wheel drives 4 (PK1), ..., 4n (PCn), which is stored in the microcontroller 9 (MK) and displayed on the remote control control 10 (PU).

Claims (1)

A hybrid vehicle with an asynchronous motor containing an onboard electric power source, an electric energy storage device, a three-phase alternating voltage electric drive energy converter and a wheel drive containing an electric motor, a microcontroller is connected to a control panel, electric motors for rotating the vehicle’s wheels are connected their shafts with shafts of rotation of the wheels of the vehicle through a differential gear, characterized eat that contains n-converters of electric energy and n-drives of wheels, where n = 2, 4, 6, 8, ..., an electrical energy storage device is connected to the on-board electric energy source, which contains storage batteries connected in series with each other, each electric converter energy contains six transistor keys, while the emitters of the first, second and third keys are respectively connected to the collectors of the fourth, fifth and sixth keys, the emitters of the first, second and third keys are connected in the first A common point that is connected to the electric energy storage device, and collectors of the fourth, fifth and sixth keys are connected to a second common point, which is connected to the midpoint between the electric energy storage batteries, each electric wheel drive contains an induction motor with stator windings, which are connected by star circuit, the beginning of the first stator winding is connected to the emitter of the second transistor switch, the beginning of the second stator winding is connected to the emitter of the first transistor switch and, the beginning of the third stator winding is connected to the emitter of the third transistor switch, the ends of the stator windings are connected to the electrical energy storage device, the key base connected to outputs of the microcontroller unit.

Images