RU72181U1 - Power semiconductor converter for diesel locomotive powered by three-phase alternating current from a synchro diesel generator with a vertical air cooling system - Google Patents

Abstract

A power semiconductor converter for a locomotive powered by a three-phase alternating current from a synchronous diesel generator with a vertical air cooling system, comprising a frame with removable front and rear shields, a left side wall and a right side wall with connectors for connecting input control circuits installed between them along the direction air flow of a group of power semiconductor thyristor modular units assembled into six three-phase electric thyristor bridges with the formation the first, second, third, fourth, fifth and sixth channels of electric energy conversion connected to internal phase conductive busbars of three-phase alternating current and rectified current buses of each conversion channel, control channels of conversion channels with protection elements of each channel, synchronization transformers of each channel, panel with fuses, characterized in that it is equipped with a first chamber for accommodating said control units, a second protective electrical insulating chamber for I have power semiconductor thyristor modular units and a holder for synchronization transformers, the first camera being made in the form of an internal side compartment located in front of the right side wall, bounded by a side window opening and U-shaped brackets fixed to it on the inside, for example, three brackets on which are fixed electrical insulating panel with the mentioned control units installed on it, over which a fiberglass cover is installed, combined

Description

The invention relates to power semiconductor converting technology, in particular, to power semiconductor converters for a diesel locomotive powered by a three-phase alternating current from a synchronous diesel generator with a vertical air cooling system. The inventive device is designed to convert a three-phase unstable alternating voltage of a diesel generator into six independently adjustable constant voltages used for separate power supply of traction DC motors.

When creating the design of the inventive device, tasks were set related to the modernization of the electric equipment of the diesel locomotive, in connection with which the developed technical solution should have:

- optimal compactness and simplicity of design with severe restrictions on weight and dimensions corresponding to the location in a special high-voltage compartment of the locomotive;

- the most rational arrangement of device blocks with the convenience of their maintenance;

- constructive security of the possibility of aggregate repair of the device due to the modularity of the blocks;

- increasing the efficiency of air cooling of all units of the device;

- increasing the reliability of electrical insulating structures with a high degree of accident-free operation and increasing the fire safety of the device;

- constructive security of the ability to easily upgrade the device.

The main technical task to be solved was to ensure a reduction in the height of the device while maintaining the dimensions of width and depth while ensuring intensification of air cooling of all units of the device and increasing the reliability of its operation, reducing fire hazard.

Currently, various designs of static converters are known.

Thus, a static converter (1) is known according to RF patent No. 2017770, containing a cabinet with front and rear doors and the power blocks of thyristors, inverter, compensator, smoothing reactors of the inverter and reverse rectifier, compensating reactor, power transformer, and automatic control unit. In this invention, the task was to simplify the design while reducing material consumption and increasing ease of maintenance. The solution to this problem was carried out only by changing the internal arrangement of the blocks, eliminating unnecessary electrical connections of the elements, eliminating unnecessary mechanical parts, for example, a rotating frame.

The disadvantages of this known design are the large overall dimensions and weight, lack of compactness, insufficient reliability in operation due to the inefficiency of air cooling of the structural units.

Known technical solutions in which they solve the problem of increasing the cooling efficiency. So, from the description of the invention to USSR author's certificate No. 1677747, the design of a power semiconductor converter (2) for high-speed electric locomotives is known, comprising a casing, two side walls of which are made opening, a main group cooler with power thyristors placed on it and an additional cooler with other functional elements, air intake device consisting of channels connected to the casing and flaps.

Uniform cooling of the internal volume of this known converter is obtained due to the opening side walls, providing free access to power thyristors and other electrical equipment. The disadvantages of this converter design are a high degree of fire hazard (due to open walls), lack of compactness and the ability to place the converter in a special compartment of a locomotive with strictly limited dimensions.

The closest in technical essence to the claimed invention is a semiconductor reversing converter with a natural air cooling system (3), containing a metal cabinet, the walls of which are perforated, between which group coolers are installed, on which semiconductor devices with individual coolers are placed. The disadvantages of this device are as follows. The design of the converter does not have a sufficiently effective air cooling system due to the irrational arrangement of the device blocks. The device is not compact enough, because of which it cannot be placed in a special compartment of the locomotive. The device does not have a sufficient degree of reliability and fire safety.

The problem to which the claimed technical solution is directed is to create an original power semiconductor converter for a diesel locomotive powered by an alternating current from a synchronous diesel generator with a vertical air cooling system, which differs from the known ones by a high degree of modernization, compactness with strictly limited dimensions at the location of the high voltage locomotive chamber, increased reliability due to improved design of electrical insulation, ease of installation and de installation of the device due to the modularity of the design, increased fire resistance by increasing the efficiency of air cooling of all units of the device.

At the same time, the achievement of the following technical and economic results should be ensured:

- improving the technical and operational characteristics of the claimed device;

- ensuring constructive compactness and the best possible use of the internal volume for placing the inventive device in the high-voltage chamber of locomotives, which guarantees unavailability of unauthorized persons to the device;

- providing convenience of service;

- the presence of a high degree of protection against emergencies in road operating conditions;

- increase the degree of fire safety due to the structural reinforcement of electrical insulation;

- improving the quality characteristics of the output voltage by increasing the efficiency of the air cooling system of all units of the device;

- increase in the duration of the maintenance-free life.

A power semiconductor converter for a locomotive powered by a three-phase alternating current from a synchronous diesel generator with a vertical air cooling system is proposed, comprising a frame with removable front and rear shields, a left side wall and a right side wall for connecting input control circuits installed between them along the air direction a stream of a group of power semiconductor thyristor modular units assembled into six three-phase electric thyristor bridges with We have the first, second, third, fourth, fifth and sixth channels of electric energy conversion connected to internal phase conductive buses of three-phase alternating current and rectified current buses of each conversion channel, and control channels of conversion channels with current protection elements for each channel, synchronization transformers of each channel panel with fuses.

The achievement of these technical results is achieved due to the fact that the device is equipped with a first camera for accommodating the control channels of the conversion channels, a second protective electrical insulating chamber for power semiconductor modular units and a holder for synchronization transformers, the first mentioned camera being made in the form of an internal side compartment located in front of the right side wall bounded by a side window opening and U-shaped brackets fixed in it from the inside for example, three U-shaped brackets, on which an electrically insulating panel is mounted with the said control channels of the conversion channels installed on it, on top of which a fiberglass cover is installed, combined with the surface of the side wall, and the second camera is made in the form of the first adjacent to each other, second and third gateways, in each of which open

in the center are two opposed bulkheads dividing the gateway into four adjacent compartments, and in each compartment there are stacks of power semiconductor thyristor modular units, each of which is fastened by individual mounting panels with vertical walls of the gateway with the possibility of forming an injector duct in the center of each gateway, and in the first gateway the first and fourth channels for converting electric energy are located opposite, in the second gateway the second and fifth channels for converting electric energy are placed gi, and in the third gateway the third and sixth channels of electric energy conversion are located opposite, and the injection ducts located in the said gateways form an injection air cooling system, while the second mentioned chamber is installed on additional mounting elements in the form of two spars installed in the lower part of the frame along both sides of its central axis, and the fuse panel is made of two symmetrical parts, each of which is mounted on the side member under the corresponding holder ransformatorov synchronization.

The claimed technical solution can be recognized as meeting the requirements of novelty, since no analogue has been found, characterized by features identical to all the essential features of the proposed object of protection.

The technical solution can be recognized as having an inventive step, since it does not explicitly follow from the prior art for a specialist.

The claimed technical solution meets the requirement of industrial applicability, since it is manufactured and used in railway transport, in particular, in passenger and freight diesel locomotives, for example, in the TEP7BS-001 diesel locomotive.

The essence of the claimed device is illustrated by the following drawings:

- figure 1 - power semiconductor converter for a diesel locomotive powered by a three-phase alternating current from a synchronous diesel generator with a vertical air cooling system; front view;

- figure 2 is the same, front view with conventionally removed front shield;

- figure 3 is the same, rear view;

- figure 4 is the same, rear view with conventionally removed back shield;

- figure 5 is the same, a top view with the location of the conventionally marked thyristor modular units 8 in the second protective electrical insulating chamber 22;

- Fig.6 is the same, a top view of the implemented technical product;

- Fig.7 is the same, view A is a view of the first camera 21 located on the right side wall of the device;

- Fig. 8 is the same, view A is with the panel 27 removed;

- Fig.9 - power converter 1 with a protective electric insulating chamber 22 placed therein; front view;

- figure 10 - power semiconductor thyristor modular unit.

The inventive power semiconductor converter for a locomotive powered by a three-phase alternating current from a synchronous diesel generator with a vertical air cooling system (hereinafter referred to as a power converter 1 - see Figs. 1-4) is a closed cabinet with two-sided maintenance and comprises a frame 2 (Fig. .1, 2, 3, 4) with removable front and rear shields 3 and 4, the left side wall 11 and the right side wall 6 with connectors 7 for connecting input control circuits. The power Converter 1 also contains installed along the air flow direction of the group of power semiconductor thyristor modular units 8 (Fig.2, 4). Each power semiconductor

thyristor module 8 (hereinafter referred to as thyristor module 8) contains (see FIG. 10) a tablet thyristor 9, for example, thyristor T 453-800-36-83-2,2 - UChL2 (TU 3417-003-41687291-97 ) mounted between individual anode and cathode coolers 10 mounted on an individual insulating mounting panel 12, on the free side of which there is a board 13 for generating control pulses of power thyristor 9.

Groups of thyristor modular units 8 are assembled into six three-phase electric thyristor bridges with the conversion of the first, second, third, fourth, fifth and sixth channels of electric energy conversion (see figures 2 and 4 - positions I, II, III, IV, V, VI ) connected to the internal phase busbars of three-phase alternating current (Fig. 1 and 3 - pos. 14 (bus A1, B1, C1 and position 15 - bus A2, B2, C2) and six (see Fig. 1,3 - position 16) rectified current buses of each conversion channel. Power converter 1 also includes control units 17 of said channels conversion lams with current protection elements of each channel (for example, with a voltage sensor of the LEM type with panels of current-limiting resistors A 17 that control the output voltage of the channels), synchronization transformers 18 of each channel, panel 19 with fuses 20. Blocks 17 perform the function of supplying a controlled supply voltage to thyristor modular units 8 of each of the six conversion channels. Power converter 1 is equipped with a first camera 21 for accommodating the conversion channel control units 17, as well as n the second protective electrical insulating chamber 22 for power semiconductor modular units 8, as well as the holder 23 of the synchronization transformers.

The first camera 21 is made in the form located in front of the right side wall 6 of the inner side compartment 24, limited by the side

a window opening 25 and U-shaped brackets 26 fixed therein on the inside, for example, three brackets 26 on which an electrically insulating panel 27 is mounted with control units 17 mounted on it. On top of the panel 27 install fiberglass cover 28, combined with the surface of the side wall 6.

The second said chamber 22 is made (see Fig. 9) in the form of first, second and third gateways 29 sequentially adjacent to each other, each of which has open bulkheads 30 in the center, dividing the gateway 29 into four adjacent compartments 31, and in each compartment 31, stacks of 32 power semiconductor thyristor modular units 8 are placed, each of which is fastened by individual mounting panels with vertical walls of the gateway 29 with the possibility of forming an injector duct 33 in the center of each gateway, and in the first gateway 29 opposite the first and fourth channels for converting electric energy are located, the second and fifth channels for converting electric energy are opposite in the second gateway, and the third and sixth channels for converting electric energy are in the third gateway, and the injection ducts 33 located in the airlocks form an air-cooled injection system (Figs. 2, 4). The second chamber 22 is mounted on additional mounting elements made in the form of spars 35 installed in the lower part of the frame on both sides of the central geometric plane parallel to the front and rear shields. The holder 23 of the synchronization transformers 18 is made in the form of two horizontal insulation panels 34 mounted under the second protective electrical insulation chamber 22 on both sides of its central axis. Panel 19 with fuses 20 is made of two symmetrical parts, each of which is mounted on the spar 35 under the corresponding holder 23 of the transformers 18 synchronization.

In the power converter 1, six isolation transformer units 36 are also located, and on the side wall of the frame 2 there are six connectors ХР1 - ХР6, for connecting the converter control circuits, the terminal block of the protective interlock circuit and the supply of zero wires to the network supply circuit for synchronization transformers.

To supply the converter power circuits from the diesel generator and to the traction motors of the six electric energy conversion channels, connecting copper buses 16 are arranged in the lower part of the cabinet 2 of the cabinet, on its two sides (Figs. 1, 3).

The power converter 1 is powered from a synchronous generator with two stator windings connected to two independent stars, the voltages of which are shifted by 30 electrical degrees. The first three autonomously controlled converter channels receive power from the first generator star, and the next three channels from the second generator star (not shown in Fig.).

The operation of the claimed device is as follows.

The power cabinet of the converter 1 is installed on seats in a special compartment of the diesel locomotive of the diesel locomotive, a ground conductor is connected to the ground bolts. Install power circuits, as well as control and control circuits of the converter in accordance with the attached electrical circuit (according to Appendix B). The power cables to the converter 1 are led from below, from two sides, they are separated by phase wires and bolted to the corresponding output busbars of the power cabinet according to Appendix A. Similarly, the power cables of the traction motors are connected to the DC output busbars.

They supply voltage to the input buses 14 and 15 of the three-phase alternating current of the power converter 1. These voltages (i.e. two three-phase unstable alternating voltages received from the diesel generator

frequency 25 ... 155 Hz, phase shifted by thirty electrical degrees and forming a six-phase voltage system) are fed to the inputs of six decoupling transformers 36. Transformed voltages, galvanically isolated and reduced 6.3 times in magnitude, are fed into the conversion channels electrical energy into six three-phase electric thyristor bridges composed of power semiconductor thyristor modular units 8. The above-mentioned modular blocks of thyristor bridges of six conversion channels provide The rectification of three-phase alternating voltages into constant independently adjustable output voltages with superimposed ripple of six-fold frequency is ensured. Independent control of the output DC voltage of each channel is carried out from an external control device of the diesel locomotive, which supplies control pulses to the control pulse generation boards 13 (FVI boards 13) by the power thyristor 9 through the six-channel split terminal blocks. A high-frequency alternating voltage of 25 kHz, 25 V amplitude is supplied to the FVI 13 through the windings of potential isolation transformers 36. The phase angle of thyristor control varies depending on the control signal from the control system.

The control units 17 for supplying voltage to the thyristor modular units 8, including synchronization transformers 18 and voltage sensors of the LEM type with panels of current-limiting resistors, are part of the phase-phase independent regulation of the DC output voltage of each channel of the converter and its protection in emergency operation.

Fuses 29 in the power circuits of the six conversion channels provide current protection of the Converter 1 in emergency and overload operating modes.

The inventive design of a power semiconductor converter for a diesel locomotive has the following technical advantages compared with known designs:

- optimal compactness with severe restrictions on dimensions (especially severe restrictions on height), corresponding to the location in a special high-voltage compartment of the locomotive;

- increasing the efficiency of air cooling by directed air flows organized by a new cooling structure - an air cooling injection system formed by injection ducts in a second electrically insulating chamber, as well as by constructively providing better cooling of the blocks due to the proposed arrangement of modular blocks in them;

- increased reliability and fire resistance by increasing the degree of electrical insulation due to the original design of the protective block of the insulating second chamber to accommodate power semiconductor thyristor modular units;

- constructive security of the possibility of aggregate repair of the device due to the modularity of the converter blocks;

- improving the ergonomic properties of the device due to the optimal rational arrangement of the blocks with the convenience of their maintenance and quick assembly / disassembly;

- providing the ability to easily and optimally inexpensively upgrade the converter.

The design of the invention ensures the achievement of the following techniques - economic results:

- improving the technical and operational characteristics of the claimed device;

- ensuring constructive compactness and the best possible use of the internal volume for placing the inventive device in the high-voltage chamber of locomotives, which guarantees unavailability of unauthorized persons to the device;

- providing convenience of service;

- the presence of a high degree of protection against emergencies in road operating conditions;

- increase the degree of fire safety due to the structural reinforcement of electrical insulation;

- improving the quality characteristics of the output voltage by increasing the efficiency of the air cooling system of all units of the device;

- increase in the duration of the maintenance-free life.

sources used in the description of the invention:

1. RF patent No.2017270, M. cl. NO5K _^7/20, publ. 1994.07.30.

2. Auth. St. USSR No. 1677747, M. cl. HO1L _^25/00, publ. 09/15/91. Bull. Number 34

3. Auto USSR No. 1352556, M. cl. HO1L _^23/34 publ. 11/15/87. Bull. No. 42 (PROTOTYPE).

Claims (1)

A power semiconductor converter for a locomotive powered by a three-phase alternating current from a synchronous diesel generator with a vertical air cooling system, comprising a frame with removable front and rear shields, a left side wall and a right side wall with connectors for connecting input control circuits installed between them along the direction air flow of a group of power semiconductor thyristor modular units assembled into six three-phase electric thyristor bridges with the formation the first, second, third, fourth, fifth and sixth channels of electric energy conversion connected to internal phase conductive busbars of three-phase alternating current and rectified current buses of each conversion channel, control channels of conversion channels with protection elements of each channel, synchronization transformers of each channel, panel with fuses, characterized in that it is equipped with a first chamber for accommodating said control units, a second protective electrical insulating chamber for I have power semiconductor thyristor modular units and a holder for synchronization transformers, the first mentioned camera being made in the form of an internal side compartment located in front of the right side wall, bounded by a side window opening and U-shaped brackets fixed to it on the inside, for example, three brackets on which are fixed electrical insulating panel with the mentioned control units installed on it, on top of which a fiberglass cover is installed, combined the surface of the side wall, and the second chamber mentioned is made in the form of first, second and third locks successively adjacent to each other, each of which has two opposite bulkheads open in the center, dividing the lock into four adjacent compartments, and stacks of power semiconductor are placed in each compartment thyristor modular blocks, each of which is fastened by individual mounting panels with vertical walls of the airlock with the possibility of forming an injector duct in the center of each airlock, in the first gateway, the first and fourth channels for converting electric energy are placed in the opposite gateway, in the second gateway the second and fifth channels for converting electric energy are placed in the third gateway, the third and sixth channels for converting electric energy are placed in the opposite gateway, and injection ducts located in the said gateways form an injection system air cooling, while the second mentioned chamber is mounted on additional mounting elements in the form of two spars installed in the lower parts of the frame on both sides of the central geometric plane parallel to the front and rear shields, and the holder of the synchronization transformers is made in the form of two insulating panels installed under the second protective insulating chamber on both sides of its central axis, and the fused panel is made of two symmetrical parts , each of which is mounted on the spar under the corresponding holder of synchronization transformers.