1. Field of the Invention
The present invention relates to a power conversion apparatus.
2. Background Art
In recent years, there have been movements not only to achieve capacity enlargement of a conversion circuit module configuring a power conversion apparatus along with the capacity enlargement of the power conversion apparatus, but also to respond to the capacity enlargement by using a plurality of conversion circuit modules in parallel.
In the example, the power conversion apparatus uses the conversion circuit modules by three, and is configured by a forward conversion apparatus, and a backward conversion apparatus. The conversion circuit modules 21 to 23 function as a backward conversion apparatus that converts a direct current voltage into an alternating current voltage, and the conversion circuit modules 24 to 26 function as a forward conversion apparatus that converts the alternating current voltage into the direct current voltage. The conversion circuit modules 1a to 1f are connected to a negative electrode side direct current wiring 19, and a positive electrode side direct current wiring 20. That is, a negative electrode terminal and the negative electrode side direct current wiring of each conversion circuit module are electrically connected to each other through fuses 18a, 18c, 18e, 18g, 18i, and 18k, and a positive electrode terminal and the positive electrode side direct current wiring are electrically connected to each other through fuses 18b, 18d, 18f, 18h, 18j, and 18l. The conversion circuit module 1a is a U phase of the backward conversion apparatus, the conversion circuit module 1b is a V phase of the backward conversion apparatus, the conversion circuit module 1c is a W phase of the backward conversion apparatus, the conversion circuit module 1d is an R phase of the forward, conversion apparatus, the conversion circuit module 1e is an S phase of the forward conversion apparatus, and the conversion circuit module 1f is a T phase of the forward conversion apparatus. Furthermore, terminals 21 to 26 are output terminals of the conversion circuit modules 1a to 1f.
When the power conversion apparatus is configured by connecting the plurality of conversion circuit modules to each other in parallel, in order to enlarge the capacity, it is possible to increase the number of parallel conversion circuit modules up to the necessary capacity, and it is possible to realize a circuit which summarizes the output terminals of each of the conversion circuit modules, as a power conversion apparatus of one phase.
Here, the configuration of the conversion circuit module will be briefly described by using
A conversion circuit module 1 is a half bridge circuit that is configured by IGBT 14a and IGBT 14b which are semiconductor switches, diodes 15a and 15b, a positive electrode terminal 11, a negative electrode terminal 12, and an output terminal 13. Furthermore, the conversion circuit module 1 is configured by a wiring that connects a capacitor 16 which is connected between the direct current wirings, and connects a gate drive circuit 17 which turns on or turns off IGBT 14a and IGBT 14b to the components. The gate drive circuit is controlled by a high order control apparatus, but a signal wiring and a power supply wiring from the high order control apparatus will be omitted in
As described above, in the capacity enlargement of the power conversion apparatus, it is possible to connect the conversion circuit modules 1 to each other in parallel by the necessary number, and it is possible to make the circuit which summarizes the output terminal of the half bridge circuit into the power conversion apparatus. However, when the conversion circuit module 1 is parallelized, if a difference is generated in the size of impedance of the wiring connecting the semiconductor switches, or a difference is generated in a waveform of a gate signal for driving the semiconductor switch, the current flowing through the semiconductor switch in synchronization with ON-OFF is in non-equilibrium. If the current non-equilibrium becomes large, element destruction may result, by making the excessive current flow through a portion of the semiconductor switch.
In the related art, when there is the large current non-equilibrium, a current value of the element which the largest current flows through is lowered up to a value that is capable of being safely operated. In this case, in order to secure the capacity of the power conversion apparatus, design is performed such, that the number of parallel conversion circuit modules is increased, and a cost increase or an increase in a space of the apparatus becomes a problem.
As a technology of solving the current non-equilibrium, JP-A-2010-193582 discloses that reactances are connected to output terminals of a plurality of conversion circuit modules. In the technology, by a magnetic coupling on the output terminal side, the electromotive force is generated in a direction of reducing the current difference, and the current is uniformized in the output terminal of each conversion circuit module.
However, in JP-A-2010-193582, for example, when the low frequency current such as 50 Hz is used, if the reactance is designed in accordance with the frequency of the output current, a reactance component becomes large, and it leads to the increase in size of the power conversion apparatus.
An object of the present invention is to reduce current non-equilibrium of each conversion circuit module, in a power conversion apparatus where a plurality of conversion circuit, modules are connected, to each other in parallel.
According to an aspect of the present invention, there is provided a power conversion apparatus that is configured by a plurality of conversion circuit modules which are connected to each other in parallel, including a first wiring that connects a positive electrode terminal of a first conversion circuit module among the conversion circuit modules, and a positive electrode side of a direct current wiring which supplies a direct current to the first conversion circuit, module, and a second wiring that connects a negative electrode terminal of a second conversion circuit module which is different from the first conversion circuit module among the conversion circuit modules, and a negative electrode side of a direct current wiring which supplies a direct current to the second conversion circuit module, in which when a direct current flows to the power conversion apparatus, the first wiring and the second wiring are arranged such that a magnetic coupling is generated between the first wiring and the second wiring.
According to the present invention, it is possible reduce current non-equilibrium of each conversion circuit module, in the power conversion apparatus where the plurality of conversion circuit modules are connected to each other in parallel.
BRIEF DESCRIPTION OF THE DRAWINGS
Hereinafter, embodiments will be described by using the drawings.
As illustrated in
Here, the magnetic coupling is a phenomenon that is generated in accordance with the law of electromagnetic induction of Faraday, and is a phenomenon in which if a current flowing through one wiring is time-changed, the current flows to a conductor which is in the vicinity of the wiring, such that a change of a magnetic field which is generated by the current flowing through the wiring becomes small. In the example of
Here, a structure of the conversion circuit module will be briefly described by using
As a shape of the wiring for making the magnetic coupling, it is possible to configure the wiring by a plurality of conductive plates, in addition to the case where the wiring is configured by a coil as illustrated in
In an apparatus 0, one phase of the power conversion apparatus is configured by connecting four of the conversion circuit modules 1a, 1b, 1c, and 1d to each other in parallel. The positive electrode terminals of the respective conversion circuit modules 1a, 1b, 1c, and 1d are connected to the through holes 2a, 2b, 2c, and 2d which are arranged in a conductive plate 5, through a screw or the like which is not illustrated in the drawing. Similarly, the negative electrode terminals of the respective conversion circuit modules 1a, 1b, 1c, and 1d are connected to the through holes 3a, 3b, 3c, and 3d which are arranged in a conductive plate 6, through the screw or the like which is not illustrated in the drawing. The conductive plate 5 and the conductive plate 6 are respectively connected to the positive electrode 9 side and the negative electrode 10 side of the direct current wiring.
Hereinafter, structures of the conductive plate 5 and the conductive plate 6 will be described while using
In the conductive plate 5, the through holes 2a, 2b, 2c, and 2d for being connected to the positive electrode terminals of the respective conversion circuit modules, are arranged, and holes 2e, 2f, 2g, and 2h for assembling the conductive plate 6 described later, are included. Moreover, a hole 2n for being connected, to the positive electrode, is also arranged. Therefore, in the conductive plate 5, slits 2h, 2i, 2j, and 2k are arranged. By the slits, the current, circuit, is formed, such that the current flows to the through holes 2a, 2b, 2c, and 2d from the positive electrode. The flow of the current is schematically illustrated by a dashed line arrow.
In the conductive plate 6, through holes 3e, 3f, 3g, and 3h for being connected to the negative electrode terminals of the respective conversion circuit modules, are arranged, and the holes 3a, 3b, 3c, and 3d for assembling the conductive plate 5, are included. Moreover, a hole 3j for being connected to the negative electrode, is also arranged. Therefore, in the conductive plate 6, a slit 3i is arranged. By the slit, the current circuit is formed such that the current flows to the negative electrode from the through holes 3e, 3f, 3g, and 3h. The flow of the current is schematically illustrated by a one dot dashed line arrow.
As illustrated in
If the wiring using the conductive plate is configured as described above, particularly, in the parallelization of the conversion circuit modules of three or more, the conductive plates which are connected to each other in parallel, and the shape of strengthening the magnetic coupling of the conductive plate which is connected to the positive electrode terminal or the negative electrode terminal of the self-conversion circuit module, and the conductive plate that is connected to the negative electrode terminal or the positive electrode terminal, of the conversion circuit module which is adjacent thereto, are determined in accordance with the same rule, and thereby, it is possible to achieve the effects of the present invention with a simple configuration.
In the structure such as the conductive plate 5 and the conductive plate 6 where the slits illustrated in
Furthermore, since being the phenomenon by generating the difference in current time-change at the time of the switching, the difference in the characteristics of a plurality of semiconductor devices which are switched in synchronization with each other, becomes a cause of the current difference, but does not disturb the effects of the present invention.
Moreover, in the above description, the current flow path is formed by arranging the slit in the conductive plate, but the current flow path may be arranged by arranging an insulating material in the conductive plate, in addition to the case where the slit is arranged.
Moreover, in the product for which the fuse is unnecessary, as illustrated in
Number | Date | Country | Kind |
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2015-033492 | Feb 2015 | JP | national |