RU2575545C1 - High-speed power-saving non-polluting safe train - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: claimed train comprises a leading car and a trailer car with 3-11 DC or AC traction motors supplied from the trolley line. Every DC motor is connected via a slip ring with the AC circuit and connected with the transformers, thyristor inverters, excitation winding, solenoid and storage batteries. Every AC motor is connected via a slip ring with the AC circuit, transformer, thyristor inverters, self-contained voltage inverter (SVI), SVI control system and self-contained voltage rectifier (SVR) control system. The SVI control system in the motor mode runs as the inverter while in the braking mode it changes over to the rectifier mode. The SVR in the motor mode runs as the rectifier while in the braking mode it changes over to the inverter mode. The stator windings of every induction motor are connected with separate units 1-10 of high-capacity capacitor banks.

EFFECT: higher power saving and non-polluting properties.

3 dwg

Description

The high-speed electric train, energy-saving, environmentally friendly and safe for people belongs to the field of railway transport and is intended for the transportation of people, equipment and various cargoes.

Known electric train, which contains an electric locomotive and electric cars, to which the contact wire supplies electric energy of direct or alternating current to drive a traction electric motor of direct current and wheel pairs (see Sidorov N.I. How the electric locomotive is arranged and works. - M .: Transport, 1974 . - 224 p.).

An analogue is the ER2-A6 contact battery train, which contains an electric locomotive in which DC traction motors are powered on electrified sections of the railway from a direct current or AC contact network through thyristor valves, and on non-electrified sections of the railway, from alkaline nickel-iron batteries, and trailed cars, under the body of which batteries are placed (see Kalinin V.K. et al. General course of railways. - M.: Transport, 1977. - 388 p. and p. 223-224).

Known diesel train, which contains a diesel locomotive with diesel generators, with DC traction motors that rotate the wheelset of the diesel locomotive, and passenger or freight cars (see Mikhalenko AA Diesel type DR. - M .: Transport, 1990 , 336 p.).

The Velaro high-speed train is known, which contains a head car with traction asynchronous AC motors, connected through a gearbox with wheel pairs, powered by a contact network, batteries with chargers and coupling cars (see Velaro / A. High-speed train Lipp, D. Ion, R. Mangler, Siemens. - World Railways. - 2009, No. 1, pp. 36-50).

Known AC electric drives with frequency regulation (G. G. Sokolovsky. M.: Publishing Center "Academy", 2006. - 278 S., rice 4.13).

An analogue is a wind turbine generator that contains a turbine, a gearbox, and an electric generator (see Wind Energy / Ed. By D De Renzo. - M.: Energoatomizdat, 1982. - 272 p.).

The prior art electric train with a locomotive containing batteries with chargers, DC traction motors connected to the wheelsets of the locomotive, and a wind generator installed in front of the locomotive (see patent GB, 1501383 A, publ. 02.15.1978).

The prior art electric train is environmentally friendly and safe for people and the environment, containing the head and trailed cars with traction engines, characterized in that it is equipped with wind turbine generators with differential devices with grids that are installed in front of the head car and on its roof , and on the roof of trailed wagons, with traction electric motors of direct or alternating current, which are connected by bolts rigidly from the underside of the trolley frame to the shaft of each electric motor ator connected to the left and right sides with semi-axes and a pair of wheels, which on examination Ratings more close analogue (See. Patent RU 2461470, publ. 10.06.2012, Bul. №26 the same applicant).

The disadvantages of the known electric trains and diesel trains are:

- when transporting people and goods by electric trains over long distances, there is not enough electric power supplied through the same wires, therefore it is required to build substations on the railway sections;

- when 1 kg of diesel fuel is burned, 1.5 kg of oxygen necessary for human life is burned, while a large amount of carbon dioxide, smoke and various harmful substances, such as lead, are released into the atmosphere, which have a harmful effect on people's health and life expectancy.

The technical result is the creation of an electric train of high speed, energy-saving, environmentally friendly and safe for people.

An electric train containing head and trailed cars with traction asynchronous AC motors connected through a gearbox with wheel pairs powered from the contact network, batteries with chargers, is characterized in that it is equipped with 3-11 traction electric motors of direct or alternating current with a capacity of 75-100 kW, the composition of the electric train contains 10-11 passenger cars, each traction DC motor of the head and trailed cars, which are made of aluminum or titanium alloys, it is connected to the electric network through an electric current collector, with a transformer, thyristor converters, field winding, a solinoid and batteries, or each traction electric motor of the head and trailer cars is connected to the electric network through a current collector, with a transformer, thyristor AC to DC converters, with autonomous voltage inverter, with the AIN control system, which in the motor mode operates in the inverter mode, with the autonomous control system AVN voltage, which operates in the rectifier mode, and in the braking mode the AIN switches to the rectifier mode, and the AVN operates in the inverter mode, inverting the voltage on the capacitor, an autonomous voltage inverter is connected to each four-pole traction induction motor with a squirrel-cage rotor with an AC fan of the head carriage and trailer cars, with field winding and with batteries, the stator of each traction electric motor of direct or alternating current is connected to the frame of the trolley through its windows are brackets coated with a layer of highly resistant polymeric material, for example Teflon, cast on the stator surface from the upper or lower side, or with brackets fixed to the stator by bolts to prevent its angular movement, and its shaft is connected to the wheels and rails of the railway, each the shaft of the traction motor on both sides is mounted on cylindrical roller bearings or on tapered roller bearings of the cassette type, the stator windings of each asynchronous motor of alternating current are connected to separate 1-10 blocks of high-voltage voltage capacitors, which are installed under the body of the head and trailed passenger cars to accumulate electric energy during periods of free driving, and braking, and transfer the accumulated electric energy of voltage capacitors to the windings of traction motors, during starting from the place of the electric train, its acceleration, the process of its movement by rail and into the electric network with low voltage, or the accumulation of electric energy capacitors and battery blocks of the total electrical network during sludge electric hangar station.

In FIG. 1 shows a general view of an electric train with head and trailed passenger cars. In FIG. 2 shows an electrical circuit for converting an alternating current of an electrical network to direct current for a direct current traction motor. In FIG. 3 shows the structure of the power section of a frequency converter with a rectifier for a traction asynchronous AC motor with a squirrel-cage rotor.

The electric train is equipped with 3-11 traction electric motors 1 of direct or alternating current with a power of 75-100 kW, the composition of the electric train contains 10-11 passenger cars, each traction electric motor of direct current of the head 2 and trailed cars 3, which are made of aluminum or titanium alloys, is connected with an electric AC network 4 through current collector 5, with transformer 6, thyristor converters 7, field winding 8, solinoid 9 and with batteries 10 or each traction electric motor 1 of alternating current heads 2 and trailed cars 3 is connected to the electric network 4 through a current collector 5, with a transformer 6, thyristor converters 7 AC to DC, with an autonomous voltage inverter, with the control system AIN 11, which in motor mode operates in inverter mode, with an autonomous system voltage control AVN 12, which operates in the rectifier mode, and in the braking mode the AIN switches to rectifier mode, and the AVN operates in the inverter mode, inverting the voltage across the capacitor 13, the autonomous inverter is voltage connected to each traction four-pole asynchronous electric motor 1 with a squirrel-cage rotor with an AC fan of the head carriage 2 and trailed cars 3, with an excitation winding (in Fig. 3, the field winding is not shown) and with batteries 10, the stator of each traction electric motor 1 of direct or alternating current is connected to the frame of the trolley 14 through its windows 15 with brackets 16 covered with a layer of highly resistant polymer material, for example Teflon, cast on the stator surface from the top or bottom side, or with brackets fixed to the stator by bolts to prevent its angular movement, and its shaft 17 is connected to the wheels 18 and to the rails 19 of the railway, each shaft of the traction motor 1 with two the torus is mounted on cylindrical roller bearings or on tapered roller bearings of cassette type 20, the stator windings of each AC asynchronous electric motor 9 are connected to individual 1-10 blocks of capacitors 21 of high-voltage voltages that are installed under the body of the head and trailed passenger cars to store electrical energy in periods of free pasture, and braking, and transmission of the accumulated electrical energy of voltage capacitors to the windings of traction motors, in d pulling away electric, its acceleration, during its movement along the rail and into the electricity network with low voltage, or electric energy storage in a capacitor and battery blocks of the general electrical network during sludge electric hangar station.

The electric train operates as follows.

In the electrified sections of the electric road, direct current traction motors 1 are powered from a contact electric network 4 of an alternating current through a current collector 5, a transformer 6 that reduces current, thyristor valves 7, in which the alternating current is converted to direct current. The shaft 17 of each traction electric motor 1 and the wheels 18, due to the friction forces with the rails 19, drive the cars of the electric train.

Consider the operation of an electric train with a traction electric motor of alternating current.

At the initial moment of operation of the electric train, the driver releases the brake pads of the wheels and connects the electric network to each traction asynchronous electric motor with squirrel-cage rotor 1 of an alternating current with a contact switch with an automatic control panel for the speed of the shaft of the traction motor (in Fig. 1, a contact switch with an automatic control panel) . Due to the electric current, electromagnetic forces drive the rotor of each traction induction electric motor 1, its shaft 17 and wheels 18, which drive the head carriage and trailed cars, the poles of the windings of the traction asynchronous alternating current motor are changed by a contact switch to move the train backward.

Electric current with alternating voltage from the mains is supplied through a current collector 5 to a transformer 6 to reduce the alternating current, by thyristor valves 7 to convert it to direct current, to chargers and batteries 10, to a stand-alone voltage inverter with an AIN 11 control system, which is in the motor the mode operates in the inverter mode, and with the control system ABH 12, which operates in the rectifier mode, and in the braking mode the AIN switches to the rectifier mode, and the AVN operates in the inverter mode, the inverter By varying the voltage across the capacitor 13 and each traction induction motor 1. Due to the electric current, electromagnetic forces drive the rotor of each traction asynchronous electric motor 1, its shaft 17 and wheels 18, which drive the head carriage and trailed cars, to move the train backward by the contact switch the poles of the windings of the traction asynchronous AC motor change.

The use of commercially available asynchronous motors with a squirrel-cage rotor of an alternating current allows to simplify its assembly and reduce the manufacturing cost, it has high reliability and simplicity of its design, associated with the absence of brushes and slip rings compared to the assembly of a DC motor, and the use of the structural power part of the frequency converter with a rectifier allows you to control the automatic speed control system of a traction asynchronous electric motor I eat AC, just like a constant current control of DC motor.

The transmission of torque from the shaft of each traction AC electric motor to the wheels allows you to develop the speed of the electric train at a rotational speed of the shaft of the asynchronous electric motor of 3000 rpm, a wheel diameter of 950 mm, from 0 to 540 km / h.

To change the direction of movement of the electric train with a contact switch, the stator poles of the traction asynchronous squirrel-cage electric motor are changed.

The accumulated electric energy in the blocks of voltage capacitors allows you to charge the batteries in the process of moving the train and in the parking lot continuously and save electricity.

The transmission of torque from the motor shaft to the wheels of the head and trailed cars allows increasing the efficiency of the electric train, reducing the manufacturing cost of the drive and extending the life of the electric train without repair, and the use of inertial forces of the cars makes it possible to smooth the mechanical losses of the electric motor efficiency.

In the electric network of the direct current railway, the contact switches installed in the head and trailed cars automatically turn off the transformer and thyristor valves, and electric current is supplied to each traction AC motor, and in the electric network of the alternating current contact switch automatically turns on the transformer and thyristor converters (in Fig. 1, the contact switch is not shown).

Batteries are used for lighting and heating cars during the sludge period of electric trains in hangars, for powering electrical appliances and other control systems.

Using blocks of voltage capacitors allows you to save the consumption of electric energy from a common electrical network and increase the efficiency of traction motors.

For the composition of a passenger electric train of 10-11 cars, 3-6 traction asynchronous AC electric motors with a power of 75-100 kW are enough.

Claims (1)

An electric train containing head and trailed cars with traction asynchronous AC motors connected via a gearbox with wheel pairs powered from the contact network, batteries with chargers, characterized in that it is equipped with 3-11 traction electric motors of direct or alternating current with a capacity of 75-100 kW, the composition of the electric train contains 10-11 passenger cars, each DC traction motor of the head and trailer cars, which are made of aluminum or titanium alloys, connected to the AC mains through a current collector, with a transformer, thyristor converters, field winding, solinoid and batteries, or each traction electric motor of the head and trailer cars is connected to the mains through a current collector, with a transformer, thyristor AC to DC converters, with autonomous voltage inverter, with AIN control system, which in the motor mode operates in inverter mode, with an autonomous control system for AVN voltage, which operates in the rectifier mode, and in the braking mode the AIN switches to the rectifier mode, and the AVN operates in the inverter mode, inverting the voltage on the capacitor, an autonomous voltage inverter is connected to each four-pole traction induction motor with a squirrel-cage rotor with an AC fan of the head carriage and trailer cars, with field winding and with batteries, the stator of each traction electric motor of direct or alternating current is connected to the frame of the trolley from its window with brackets covered with a layer of highly resistant polymer material, for example Teflon, cast on the stator surface from the top or bottom side, or with brackets fixed to the stator by bolts to prevent its angular movement, and its shaft is connected to the wheels and rails of the railway, each shaft of the traction motor on both sides is mounted on cylindrical roller bearings or on tapered roller bearings of cassette type, the stator windings of each asynchronous motor the alternating current is connected to separate 1-10 blocks of high-voltage voltage capacitors, which are installed under the body of the head and trailed passenger cars to accumulate electrical energy during periods of free driving, and braking, and transfer the accumulated electric energy of voltage capacitors to the windings of traction motors, during starting from the place of the electric train, its acceleration, the process of its movement by rail and into the electric network with low voltage, or the accumulation of electric energy and in blocks of capacitors and accumulators from a common electrical network during the period of stagnation of an electric train in the hangar of a railway station.

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