Patent Application
20140347898
Embodiments of the present disclosure are related to power conversion systems, and more particularly to a multi-level power conversion system.
Power conversion systems are often used to convert alternating current (AC) power to direct current power (DC) at a transmitting substation and to convert the transmitted DC power back to AC power at a receiving substation in high voltage direct current (HVDC) transmissions. In one approach, such power conversion systems have a modular multi-level structure. The modular multi-level structure includes a stacked arrangement of power converter modules for converting AC power to DC power and DC power to AC power.
Various designs of power converter modules have been employed to form modular multi-level power conversion systems. One such design of the power converter modules includes a half bridge which in turn includes two switches coupled across a capacitor. Such a half bridge module is susceptible to DC faults, for example, a DC short circuit. Moreover, the half bridge module is incapable of limiting such short circuit currents.
Furthermore, a full bridge power converter module has been employed to overcome the shortcomings of the half bridge module. The full bridge power converter module, while capable of limiting the DC short circuit current, entails use of twice the number of switches as the half bridge structure. Such an increased number of switches result in higher losses and costs.
Additionally, a double clamped power converter module has also been employed to limit the short circuit current. Switches in the double clamped power converter module have a power rating between the power ratings of the switches of the half bridge power converter module and the full bridge power converter module. However, the double clamped power converter module includes additional electronic components in comparison to the full bridge power converter module. Use of these additional electrical components leads to higher costs and complexities in a modular approach.
Lately, another approach has been used to design the power converter module. This approach includes two switches and two capacitors in each power converter module. Such a power converter module allows easier insulation and better cooling during operation. However, this configuration fails to limit the short circuit current under DC fault conditions.
In accordance with an aspect of the present disclosure, a power converter module is provided. The power converter module includes a first converter leg and a second converter leg. The first converter leg includes a first switching unit and a second switching unit coupled in series. The second switching unit is disposed in a reverse orientation with respect to an orientation of the first switching unit. The second converter leg includes a third switching unit and a diode coupled in series. The third switching unit is disposed in a reverse orientation with respect to the orientation of the first switching unit. The power converter module also includes a first energy storage device operatively coupled between the first converter leg and the second converter leg. The power converter module further includes a second energy storage device operatively coupled between the first converter leg and the second converter leg.
In accordance with another aspect of the present disclosure, a power conversion system is provided. The power conversion system includes a plurality of phase units, where each phase unit is configured to convert power corresponding to a respective phase of an input power. Also, each phase unit includes a plurality of power converter modules coupled in series to each other. Moreover, each power converter module includes a first converter leg and a second converter leg. The first converter leg includes a first switching unit and a second switching unit coupled in series. The second switching unit is disposed in a reverse orientation with respect to an orientation of the first switching unit. The second converter leg includes a third switching unit and a diode coupled in series. The third switching unit is disposed in a reverse orientation with respect to the orientation of the first switching unit. The power converter module also includes a first energy storage device and a second energy storage device operatively coupled between the first converter leg and the second converter leg.
In accordance with yet another aspect of the present disclosure, a method for converting power is provided. The method includes coupling a first switching unit and a second switching unit in series to form a first converter leg, where the second switching unit is disposed in a reverse orientation with respect to an orientation of the first switching unit. The method also includes coupling a third switching unit and a diode coupled in series to form a second converter leg, where the third switching unit is disposed in a reverse orientation with respect to the orientation of the first switching unit. The method further includes operatively coupling a first energy storage device and a second energy storage device between the first converter leg and the second converter leg to form a power converter module. The method also includes operatively coupling a plurality of power converter modules to form a power conversion system configured to convert an input power to an output power. The method further includes limiting a fault condition in the power conversion system upon identifying the fault condition to minimize a DC fault current in the power conversion system.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Unless defined otherwise, technical and scientific terms used herein have the same meaning as is commonly understood by one of ordinary skill in the art to which this disclosure belongs. The terms “first”, “second”, and the like, as used herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. Also, the terms “a” and “an” do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced items. The term “or” is meant to be inclusive and mean one, some, or all of the listed items. The use of “including,” “comprising” or “having” and variations thereof herein are meant to encompass the items listed thereafter and equivalents thereof as well as additional items. The terms “connected” and “coupled” are not restricted to physical or mechanical connections or couplings, and can include electrical connections or couplings, whether direct or indirect. Furthermore, the terms “circuit,” “circuitry,” “controller,” and “processor” may include either a single component or a plurality of components, which are either active and/or passive and are connected or otherwise coupled together to provide the described function.
Aspects of the present disclosure are related to a power converter module and a power conversion system including the power converter module. In one embodiment, the power conversion system may include a high voltage direct current (HVDC) transmission system, a power distribution system, an electrical machine control system, or a combination thereof. The power conversion system includes a plurality of phase units. Moreover, each phase unit is configured to convert power corresponding to a respective phase of an input power. Furthermore, each phase unit includes a plurality of power converter modules coupled in series to each other.
The power converter module may include a first converter leg and a second converter leg. The first converter leg may include a first switching unit and a second switching unit coupled in series. The second switching unit may be disposed in a reverse orientation with respect to an orientation of the first switching unit. Furthermore, the second converter leg may include a third switching unit and a diode coupled in series. The third switching unit may be disposed in a reverse orientation with respect to the orientation of the first switching unit. Moreover, the power converter module may also include a first energy storage device and a second energy storage device operatively coupled between the first converter leg and the second converter leg.
Furthermore, the plurality of source side phase units 50 may include a plurality of source power converter modules 55 operatively coupled in series to each other. Similarly, the plurality of load side phase units 60 may include a plurality of load power converter modules 65 operatively coupled in series to each other. Moreover, the source side power conversion system 20 may be operatively coupled to a source side controller 70 and the load side power conversion system 30 may be operatively coupled to a load side controller 80. The source side controller 70 may be configured to control switching operations of the source power converter modules 55 to generate the DC power from the AC power. During normal operation, each of the source power converter modules 55 may be controlled independently by the source side controller 70 to provide a zero voltage or a positive voltage at respective electrical terminals to generate the source voltage of the respective phase in the HVDC transmission system 10. The zero voltages or the positive voltages may be added to generate the source voltage for the respective phase. Similarly, the source voltage corresponding to other phases may be generated by controlling the source power converter modules 55 of respective source side phase units 50. Moreover, the load power converter modules 65 may also be similarly controlled by the load side controller 80 to regulate a load side voltage or current. Furthermore, during a fault condition such as a short circuit at the DC link 40, the power converter modules 55 and 65 may be controlled to provide a negative voltage in opposition to alternating current phase voltages on the source side power conversion system 20 and the load side power conversion system 30 for reducing a DC fault current.
The first converter leg 120 may include a first node 122, a second node 124, and a third node 126. The first node 122 may be operatively coupled to the first terminal node 112 of the electrical terminal 110. The third node 126 may be operatively coupled to the second terminal node 114 of the electrical terminal 110. Furthermore, the first converter leg 120 may also include a first switching unit 140 and a second switching unit 150 coupled in series to each other. The first switching unit 140 may be disposed between the first node 122 and the second node 124 of the first converter leg 120. Furthermore, the second switching unit 150 may be disposed between the second node 124 and the third node 126 of the first converter leg 120. Moreover, the second converter leg 130 may include a fourth node 132, a fifth node 134, and a sixth node 136. The second converter leg 130 may also include a third switching unit 160 and a diode 170. Furthermore, the third switching unit 160 may be disposed between the fourth node 132 and the fifth node 134 of the second converter leg 130. The diode 170 may be disposed between the fifth node 134 and the sixth node 136 of the second converter leg 130.
Furthermore, the first switching unit 140 may include a first switch 142 and a first switching diode 144. Similarly, the second switching unit 150 may include a second switch 152 and a second switching diode 154. Moreover, the third switching unit 160 may include a third switch 162 and a third switching diode 164. In one embodiment, the first switch 142 may be operatively coupled in an anti-parallel configuration to the first switching diode 144, while the second switch 152 may be operatively coupled in an anti-parallel configuration to the second switching diode 154. The third switch 162 may be operatively coupled in an anti-parallel configuration with respect to the third switching diode 164.
In one embodiment, the first switch 142, the second switch 152, and the third switch 162 may include insulated gate bipolar transistor (IGBT) switches, mechanical switches, or a combination thereof. It may be noted that the second switching unit 150 and the third switching unit 160 may be disposed in a reverse orientation with respect to an orientation of the first switching unit 140. In particular, the second switch 152 and the third switch 162 may be disposed in a reverse orientation with respect to an orientation of the first switch 142. It may be noted that each of the first switch 142, the second switch 152, and the third switch 162 includes an anode or a collector and a cathode or an emitter. The collector of the first switch 142 may be coupled to the first terminal node 112 of the electrical terminal 110. The emitter of the first switch 142 may be coupled to the emitter of the second switch 152. Moreover, the collector of the second switch 152 may be coupled to the second terminal node 114 of the electrical terminal 110. Also, the emitter and the collector of the third switch 162 may be coupled to the fourth node 132 and the diode 170 respectively. Similarly, the second switching diode 154 and the third switching diode 164 may be operatively coupled in a reverse orientation with respect to an orientation of the first switching diode 144.
Additionally, the power converter module 100 may also include a first energy storage device 180 and a second energy storage device 190. The first energy storage device 180 may be operatively coupled between the first node 122 and the fourth node 132. Also, the second energy storage device 190 may be operatively coupled between the second node 124 and the fifth node 134. In one embodiment, the first energy storage device 180 and the second energy storage device 190 may be operatively coupled in opposing polarities with respect to each other. The first energy storage device 180 and the second energy storage device 190 may provide a positive voltage or a zero voltage at the electrical terminal 110 of the power converter module 100. In one embodiment, the first energy storage device 180 and the second energy storage device 190 may include a capacitor. Also, in one embodiment, the power converter module 100 may be configured as the source power converter module 55 of
In situations of a fault in a DC link, the power converter module 100 may be configured to generate a negative voltage at the electrical terminal 110 to minimize a DC fault current and limit the fault. In one embodiment, the fault may include a DC fault in the DC link 40 (see
Referring now to
The power converter module 100 is operatively coupled to the controller 200 that may be configured to control the switching operations of the power converter module 100 to generate the negative voltage. The controller 200 may be configured to control the first switching unit 140, the second switching unit 150, and the third switching unit 160 of the power converter module 100 to limit the fault condition. The controller 200 may be configured to either maintain the first switch 142, the second switch 152, and the third switch 162 at a non-conducting state or transition the first switch 142, the second switch 152, and the third switch 162 to the non-conducting state. Consequently, due to the inherent property of current to flow through a path of least resistance, the DC fault current flows from the second terminal node 114 through the diode 170, the second energy storage device 190, and the first switching diode 144 to the first terminal node 112. Due to the aforementioned negative voltage current path, the voltage at the electrical terminal 110 is negative and equal in magnitude to the voltage across the second energy storage device 190. Such a negative voltage provided by the power converter module minimizes the DC fault current by opposing the alternating current (AC) voltage on the source side power conversion system (see
Turning now to
Furthermore, the first switching unit 740 may include a first switch 742 and first switching diode 744. Similarly, the second switching unit 750 may include a second switch 752 and a second switching diode 754. Moreover, the third switching unit 760 may include a third switch 762 and a third switching diode 764. In one embodiment, the first switch 742 may be operatively coupled in an anti-parallel configuration to the first switching diode 744, while the second switch 752 may be operatively coupled in an anti-parallel configuration to the second switching diode 754. The third switch 762 may be coupled in an anti-parallel configuration to the third switching diode 764. In certain embodiments, the first switch 742, the second switch 752, and the third switch 762 may include insulated gate bipolar transistor (IGBT) switches, mechanical switches, or a combination thereof. It may be noted that the second switching unit 750 and the third switching unit 760 may be disposed in a reverse orientation with respect to an orientation of the first switching unit 740. In particular, the second switch 752 and the third switch 762 may be disposed in a reverse orientation with respect to an orientation of the first switch 742.
In one embodiment, each of the first switch 742, the second switch 752 and the third switch 762 includes an anode or a collector and a cathode or an emitter. The collector of the first switch 742 may be coupled to the collector of the second switch 752. The emitter of the first switch 742 may be coupled to the second terminal node 714. Moreover, the emitter of the second switch 752 may be coupled to the first terminal node 712 of the electrical terminal 710. Also, the collector and the emitter of the third switch 762 may be coupled to sixth node 736 and the diode 770 respectively. Similarly, the second switching diode 754 and the third switching diode 764 may be disposed in a reverse orientation with respect to an orientation of the first switching diode 744.
Additionally, the power converter module 700 may also include a first energy storage device 780 and a second energy storage device 790. The first energy storage device 780 may be operatively coupled between the third node 726 and the sixth node 736. Also, the second energy storage device 790 may be operatively coupled between the second node 724 and the fifth node 734. In one embodiment, the first energy storage device 780 and the second energy storage device 790 may be operatively coupled to each other in polarities opposite with respect to each other. Furthermore, a controller 795 may be coupled to the power converter module 700 and may be configured to control switching operations of the first switching unit 740, the second switching unit 750, and the third switching unit 760 in the power converter module 700.
In the embodiment of
In accordance with further aspects of the present disclosure, additional switching units and energy storage devices may be included in the power converter module 100 of
Furthermore, the first converter leg 920 may also include a fourth switching unit 980. Similarly, the second converter leg 930 may also include a fifth switching unit 990. The fourth switching unit 980 may be operatively coupled between the third node 926 and the fourth node 928 in the first converter leg 920. Also, the fifth switching unit 990 may be operatively coupled between the seventh node 936 and the eighth node 938.
Moreover, the first switching unit 940 may include a first switch 942 and first switching diode 944. Similarly, the second switching unit 950 may include a second switch 952 and a second switching diode 954. Moreover, the third switching unit 960 may include a third switch 962 and a third switching diode 964. Furthermore, the fourth switching unit 980 may include a fourth switch 982 and a fourth switching diode 984. Also, the fifth switching unit 990 may include a fifth switch 992 and a fifth switching diode 994. In one embodiment, the first switch 942 may be operatively coupled in an anti-parallel configuration to the first switching diode 944, while the second switch 952 may be operatively coupled in an anti-parallel configuration to the second switching diode 954. Similarly, the third switch 962 may be operatively coupled in an anti-parallel configuration to the third switching diode 964 and the fourth switch 982 may be operatively coupled in an anti-parallel configuration to the fourth switching diode 984. Moreover, the fifth switch 992 may be operatively coupled in an anti-parallel configuration to the fifth switching diode 994. In one embodiment, the first switch 942, the second switch 952, the third switch 962, the fourth switch 982 and the fifth switch 992 may include insulated gate bipolar transistor (IGBT) switches, mechanical switches, or a combination thereof.
It may be noted that the first switching unit 940 and the fourth switching unit 980 may have similar orientations. The second switching unit 950, the third switching unit 960 and the fifth switching unit 990 may be disposed in a reverse orientation with respect to the orientation of the first switching unit 940 and the fourth switching unit 980. In particular, the second switch 952, the third switch 962, and the fifth switch 992 may be disposed in a reverse orientation with respect to an orientation of the first switch 942 and the fourth switch 982. Furthermore, each of the first switch 942, the second switch 952, the third switch 962, the fourth switch 982, and the fifth switch 992 may include an anode or a collector and a cathode or an emitter. The collector of the first switch 942 may be coupled to the first terminal node 912 of the electrical terminal 910. The emitter of the first switch 942 may be coupled to the emitter of the second switch 952. Moreover, the collector of the second switch 952 may be coupled to the collector of the fourth switch 982. The emitter of the fourth switch 982 may be coupled to the second terminal node 914. Also, the emitter and the collector of the third switch 962 may be coupled to the first terminal node 912 and the diode 970 respectively. Also, the emitter and the collector of the fifth switch 992 may be coupled to the diode 970 and the second terminal node 914 respectively. Furthermore, the second switching diode 954, the third switching diode 964 and the fifth switching diode 994 may be disposed in a reverse orientation with respect to an orientation of the first switching diode 944 and the fourth switching diode 984.
Additionally, the power converter module 900 may also include a first energy storage device 1000, a second energy storage device 1010, a third energy storage device 1020, and a fourth energy storage device 1030. The first energy storage device 1000 may be operatively coupled between the first node 922 and the fifth node 932. Also, the second energy storage device 1010 may be operatively coupled between the second node 924 and the sixth node 934. Similarly, the third energy storage device 1020 may be operatively coupled between the third node 926 and the seventh node 936. The fourth energy storage device 1030 may be operatively coupled between the fourth node 928 and the eighth node 938. In one embodiment, the first energy storage device 1000 and the third energy storage device 1020 may be arranged in a first orientation, while the second energy storage device 1010 and the fourth energy storage device 1030 may be operatively coupled in a second orientation, where the second orientation is opposite to the first orientation.
During a fault in a DC link such as the DC link 40 (see
Furthermore, at step 1330, a first energy storage device and a second energy storage device may be operatively coupled between the first converter leg and the second converter leg to form a power converter module. In one embodiment, the method 1300 may further include operatively coupling a third energy storage device and a fourth energy storage device in opposing polarities between the first converter leg and the second converter leg. Moreover, as indicated by step 1340, a plurality of power converter modules may be operatively coupled to form a power conversion system configured to convert an input power to an output power.
During a fault condition in the power conversion system, a DC fault current may be induced in one or more power converter modules. In accordance with exemplary aspects of the present disclosure, once a fault condition is identified, a controller may be configured to aid in controlling a flow of the DC fault current. By way of example, the controller may be configured to energize or de-energize one or more switching units to force the DC fault current to follow a negative voltage current path. Accordingly, at step 1350, the fault condition may be limited by generating a negative voltage at corresponding electrical terminals of the plurality of power converter modules. In one embodiment, the negative voltage may be used to minimize the DC fault current, which in turn aids in limiting the fault condition.
It is to be understood that a skilled artisan will recognize the interchangeability of various features from different embodiments and that the various features described, as well as other known equivalents for each feature, may be mixed and matched by one of ordinary skill in this art to construct additional systems and techniques in accordance with principles of this disclosure. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
The exemplary embodiments of the power converter module described hereinabove aid in reducing a DC fault current and limiting a fault condition in a power conversion system. The exemplary power converter modules also entail use of fewer electronic components, which in turn reduces the cost of the power converter modules. The use of fewer electronic components also reduces the complexity of the power converter modules and enables easier packaging of the power converter modules.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
This application is a continuation-in-part of U.S. patent application Ser. No. 13/484,517, entitled “MULTI-LEVEL POWER CONVERTER,” filed on May 31, 2012, which is herein incorporated by reference.
| Number | Date | Country | |
|---|---|---|---|
| Parent | 13484517 | May 2012 | US |
| Child | 14453637 | US |
