Patent Application
20150171770
The present disclosure relates generally to renewable energy sources, and more particularly to a system and method for improving the total output power capability of power converters used in renewable energy applications.
Power converters are used in renewable energy applications to convert electrical power generated by a renewable energy source into power that is suitable for supply to an AC grid. For example, power converters can be used in wind energy applications to convert the alternating current generated by a wind turbine to a desired output frequency (e.g. 50/60 Hz) and voltage level. Power converters can be used in solar energy applications to convert the DC power generated by one or more photovoltaic arrays into suitable AC power for the AC grid.
Power converters typically use a plurality of switching devices, such as insulated gate bipolar transistors (IGBTs) to convert power supplied from an input power source to a suitable output AC power for the AC grid. For instance, the power converters can include a plurality of switching modules with each switching module including an upper switching element and a lower switching element coupled in series. An output of the switching module can be coupled between the upper switching element and the lower switching element. The switching module can further include a diode coupled in parallel with each of the upper switching element and the lower switching element.
The switching performance of the switching elements used in the power converter can have a significant impact on the output of the power converter. This is particularly true in high power converter applications where multiple switching modules are operated in parallel. In these applications, it can be important to balance the current sharing among the parallel switching modules while also controlling the peak voltage on the parallel switching modules. In particular, any imbalance in the current sharing between parallel switching modules can limit the total output current by the highest stressed switching module, with the lower stressed switching modules not achieving their full capability. As a result, current imbalance among the parallel modules can lead to reduced output capability for the power converter.
Balanced current sharing among the parallel switching modules promotes increased reliability. Achieving balanced current sharing among the parallel modules can be difficult, however, as a result of the differing physical current paths for the switching modules due to, for instance, the internal layout of switching modules and bus bars in the power converter. In addition, the switching performance of the upper and lower switching elements in the switching modules can have an impact on current sharing among parallel switching modules.
The switching performance of the switching elements in the switching modules can depend a lot on the gate resistors used in association with gate driver circuits used to drive the switching elements in the switching modules. In typical applications, gate circuits associated with a switching module include the same type of gate resistor network for both the upper and lower switching elements in the switching module. It has been discovered, however, that it can be difficult to select a single type of gate resistor network for both the upper and lower switching elements that provides good switching performance for both the upper and lower switching elements across a wide range of operating conditions, such as different voltages, currents, and or operating temperatures.
Thus, a need exists for a gate circuit design that improves the switching performance of both the upper switching elements and the lower switching elements used in a power converter across a wide range of operating conditions. A gate circuit design that improves current balancing among parallel switching modules in a high power converter would be particularly useful.
Aspects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.
One exemplary aspect of the present disclosure is directed to a power converter for converting an input power to an output AC power at a grid frequency. The power converter includes a switching module having a first switching element and a second switching element coupled in series and an output coupled between the first switching element and the second switching element. The power converter includes a driver circuit coupled to the at least one switching module. The driver circuit is configured to provide one or more signals to control switching of the first switching element and the second switching element. The power converter further includes a first gate resistor network coupled between the driver circuit and the first switching element and a second gate resistor network coupled between the driver circuit and the second switching element. Characteristics of the first gate resistor network are different from characteristics of the second gate resistor network.
For instance, characteristics of the first gate resistor network can be selected to improve switching performance of the first switching element by reducing a switching performance parameter (e.g. a voltage oscillation magnitude) for the first switching element. Characteristics of the second gate resistor network can be selected independently of the characteristics of the first gate resistor network to improve switching performance by reducing a switching performance parameter (e.g. a voltage oscillation magnitude) of the second switching element.
Another exemplary aspect of the present disclosure is directed to a method for increasing the output power of a power converter. The power converter includes at least one switching module. The switching module includes a first switching element and a second switching element coupled in series. The power converter further includes a driver circuit configured to provide one or more signals to control switching of the first switching element and the second switching element. The power converter further includes a first resistor network coupled between the driver circuit and the first switching element and a second resistor network coupled between the driver circuit and the second switching element. The method includes selecting characteristics of the first resistor network to improve switching performance of the first switching element; and selecting characteristics of the second resistor network independently of the first resistor network to improve switching performance of the second switching element.
Yet a further exemplary aspect of the present disclosure is directed to a power converter for use in a renewable energy application. The power converter includes a converter configured to convert an input power received from an input power source to DC power and to provide the DC power to a DC link. The power converter further includes an inverter configured to convert the DC power on the DC link to AC power at an AC grid frequency. One or more of the converter or the inverter includes at least one switching module. The switching module includes a first switching element and a second switching element coupled in series. The power converter further includes a gate circuit associated with the switching module. The gate circuit includes a driver circuit configured to provide one or more signals to control switching of the first switching element and the second switching element. The gate circuit further includes a first gate resistor network coupled between the driver circuit and the first switching element and a second gate resistor network coupled between the driver circuit and the second switching element. Characteristics of the first gate resistor network are different from characteristics of the second gate resistor network.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
A full and enabling disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended figures, in which:
Reference now will be made in detail to embodiments of the invention, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope or spirit of the invention. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present invention covers such modifications and variations as come within the scope of the appended claims and their equivalents.
Generally, the present disclosure is directed to a system and method for improving the output power capability of a power converter used to convert input power from an input power source, such as a photovoltaic array, a fuel cell, or a wind turbine, to an output AC power at a grid frequency (e.g. 50/60 Hz) suitable for application to an AC grid. The power converter can include a plurality of switching modules coupled in parallel to provide increased output power capability of the power converter. Each of the switching modules includes an upper switching element (such as an insulated gate bipolar transistor (IGBT)) coupled in series with a lower switching element. The upper switching element can be coupled in parallel with a first diode and the lower switching element can be coupled in parallel with a second diode. An output of the switching module can be coupled between the upper switching element and the lower switching element.
A driver circuit can be configured to provide one or more signals to control switching of the upper switching element and the lower switching element to provide a desired output. The driver circuit can provide signals to the upper switching element through a first gate resistor network and can provide signals to the lower switching element through a second gate resistor network. The switching performance of the upper switching element and the lower switching element can depend significantly on characteristics of their associated gate resistor networks.
It has been discovered that the commutating inductances of the upper switching element and the lower switching element in power converters can be different. Without being bound to any particular theory of operation, the commutating inductances of the upper and the lower switching element can be different as a result of reverse recovery characteristics of diodes used in association with the switching modules coupled with stray inductances in the power converter. The differing commutating inductances of the upper switching element and the lower switching element can make it difficult to identify a single gate resistor characteristic which can provide ideal switching performance for both the upper and lower switching element across a wide range of operating conditions, such as across different voltages and currents and different operating temperatures.
To enhance the switching performance of both the upper and the lower switching elements in the switching module, aspects of the present disclosure are directed to independently selecting different gate resistor characteristics for the upper switching element and the lower switching element to improve switching performance, for instance by reducing voltage oscillations during switching, of both the upper and the lower switching element.
According to particular aspects of the present disclosure, the independently selected gate resistor designs for the upper and lower switching element can be provided on the same gate circuit board. As a result, both the upper and the lower switching elements can obtain improved switching performance, including reduced switching losses and reduced peak voltage, with a single gate circuit board. The single gate circuit board can provide improved switching performance across a wide variety of operating conditions. The improved switching performance can increase current balance among parallel switching modules, leading to increased output power of the power converter.
The power converter system 100 includes a power converter 105 and a control system 150 configured to control operation of the power converter 105. The power converter 105 is used to convert DC power generated by one or more photovoltaic array(s) 102 into AC power suitable for feeding to the AC grid. The power converter 105 depicted in
The DC to DC converter 110 can be a boost converter configured to boost the DC voltage supplied by the PV array(s) and to provide the DC voltage to a DC link 120. The DC link 120 couples the DC to DC converter 110 to the inverter 130. As illustrated, the DC to DC converter 110 can include one or more bridge circuits 112, 114, and 116. Each of the bridge circuits 112, 114, and 116 can include a plurality of switching modules used to generate the DC power provided to the DC link 120. Each of the plurality of input bridge circuits 112, 114, and 116 can be associated with an input feed line to the DC to DC converter 110. DC to DC converter 110 can be a part of or integral with inverter 130 or can be a separate stand alone structure. In addition, more than one DC to DC converter 110 can be coupled to the same inverter 130 through one or more DC links. While a boost converter is depicted in
The inverter 130 converts the DC power provided to the DC link 120 into AC power at a grid frequency suitable for feeding to the AC grid. The inverter 130 can be configured to provide a multiphase output, such as a three-phase output to the AC grid. The inverter 130 can include a plurality of inverter bridge circuits 132, 134, and 136. Each of the plurality of inverter bridge circuits 132, 134, and 136 can be associated with an output phase of the power converter 105. Similar to the input bridge circuits, each of the plurality of inverter bridge circuits can include a plurality of switching modules, such as IGBT modules, coupled in parallel to provide increased power output capability of the power converter systems.
Control system 150 can include one or more controllers or other control devices configured to control various components of the power converter system 100, including both the DC to DC converter 110 and the inverter 130. For instance, the control system 150 can send gate timing commands to the DC to DC converter 110 to regulate the output of the DC to DC converter 110 pursuant to a control method that regulates the duty cycles of the switching elements (e.g. IGBTs, metal oxide semiconductor field effect transistors (MOSFETs), or other power electronic devices) used in the DC to DC converter 110. Control system 150 can also regulate the output of inverter 130 by providing gate timing commands to switching elements (e.g. IGBTs, MOSFETs or other power electronic devices) in the inverter 130. The gate timing commands control the pulse width modulation provided by switching devices to provide a desired real and/or reactive output by the inverter 130.
Control system 150 can also be used to control various other components of the power converter system 100, such as circuit breakers, disconnect switches, and other devices to control operation of the power converter system 100. The control system 150 can include any number of control device(s) such as processor(s), microcontroller(s), microcomputer(s), programmable logic controller(s), application specific integrated circuit(s) or other suitable control device(s).
In one aspect, the control system 150 can include one or more memory element(s) including, but not limited to, RAM, ROM, hard drives, flash drives, or other memory devices. Such memory element(s) may generally be configured to store suitable computer-readable instructions that, when implemented by a processor(s), configure the control system 150 to perform various functions including, but not limited to, transmitting suitable control signals to one or more components of the power converter system 100. Additionally, the control system 150 can also include one or more communications interfaces to facilitate communications between the control system and the various components of the power converter system 100.
As shown, inverter bridge circuit 132 includes a plurality of switching modules 210 and 220 coupled in parallel. The switching modules 210 and 220 provide a common output that serves as the output A of the inverter 130. Although, two switching modules 210 and 220 are illustrated in
Each of the switching modules 210 includes at least one switching circuit 215 that includes an upper switching element 212 and a lower switching element 214. In a particular embodiment, the upper switching element 212 and the lower switching element 214 can include insulated gate bipolar transistors (IGBTs). However, other suitable power electronic devices could be used as upper switching element 212 and lower switching element 214. For instance, the switching elements 212 and 214 could be power metal oxide semiconductor field effect transistors (MOSFETs) or other suitable switching devices.
The switching modules 210 and 220 depicted in
An exemplary switching circuit 215 can be arranged as follows. The upper switching element 212 can be a first IGBT that includes a first gate terminal, a first collector terminal, and a first emitter terminal. The lower switching element 214 can be a second IGBT that includes a second gate terminal, a second collector terminal, and a second emitter terminal. The first IGBT and the second IGBT can be arranged such that the first emitter terminal is coupled to the second collector terminal. An output of the switching circuit can be coupled between the first IGBT and the second IGBT where the first emitter terminal is coupled to the second collector terminal. The switching circuit 215 can include a first diode coupled in parallel with the first IGBT and a second diode coupled in parallel with the second IGBT.
As shown in
Gate circuit 240 includes a driver circuit 242 configured to generate a voltage signal to control the switching of upper switching element 212 and lower switching element 214 pursuant to control commands received from the control system 150. The driver circuit 242 can include one or more electronic devices configured to generate a voltage signal suitable to drive the upper switching element 212 and the lower switching element 214. The gate circuit 240 further includes a first gate resistor network 250 coupled between the driver circuit 242 and the upper switching element 212 and a second gate resistor network 260 coupled between the driver circuit 242 and the lower switching element 214. According to particular aspects of the present disclosure, the driver circuit 242, the first gate resistor network 250, and the second gate resistor network 260 can be provided on the same circuit board 255.
The first gate resistor network 250 can include a first turn on resistor 252 and a first turn off resistor 254. The driver circuit 242 can be configured to provide gate signals to the upper switching element 212 through the first turn on resistor 252 when the driver circuit 242 activates or turns on the upper switching element 212. The driver circuit 242 can be configured to provide gate signals to the upper switching element 212 through the first turn off resistor 254 when the upper switching element 212 is not activated or is off.
Similar to the first gate resistor network 250, the second gate resistor network 260 can include a second turn on resistor 262 and a second turn off resistor 264. The driver circuit 242 can be configured to provide gate signals to the upper switching element 212 through the second turn on resistor 262 when the driver circuit 242 activates or turns on the lower switching element 214. The driver circuit 242 can be configured to provide gate signals to the lower switching element 214 through the second turn off resistor 264 when the lower switching element 214 is not activated or is off.
As will be discussed in more detail below, it has been discovered that the upper switching element 212 and the lower switching element 214 can have different commutating inductances during operation due to, for instance, characteristics of the diodes coupled in parallel with the switching elements 212 and 214 as well as the location of the switching elements 212 and 214 within the power converter. As a result, it can be difficult to specify a gate resistor network that can be suitable for both the upper switching element 212 and the lower switching element 214 across a wide range of operating conditions, such as different temperature conditions.
As a result, aspects of the present disclosure are directed to selecting characteristics of the first resistor network 250 to improve switching performance (e.g. by reducing a switching performance parameter such as a voltage oscillation magnitude) of the upper switching element 212 across a wide range of conditions, such as across an operating temperature range from 25° C. to 125° C. Characteristics of the second resistor network 260 are then selected independently of the characteristics of the first resistor network 250 to improve switching performance (e.g. by reducing a switching performance parameter such as a voltage oscillation magnitude) of the lower switching element 214 across a wide range of operating conditions, such as across an operating temperature range from 25° C. to 125° C. The first resistor network 250 and the second resistor network 260 can then be provided on the same gate circuit board to provide an improve gate circuit design for the power converter system 100.
In this manner, characteristics of the first gate resistor network 250 are selected to be different from characteristics of the second gate resistor network 260 to improve the switching performance of both the upper switching element 212 and the lower switching element 214. More particularly, the first turn on resistor 252 of the first gate resistor network 250 can have a resistance that is different from a resistance of the second turn on resistor 262 of the second gate resistor network 260. Alternatively or in addition, the first turn off resistor 254 of the first gate resistor network 250 can have a resistance that is different from a resistance of the second turn off resistor 264 of the second gate resistor network 260.
To illustrate the advantages of selecting characteristics of the first gate resistor network independent of characteristics of the second gate resistor network, an exemplary application of the present disclosure will now be provided. A pulse test was conducted for both an upper switching element 212 and a lower switching element 214 of a Fuji 6MBI450U4-120 switching module with varying gate resistor networks for both the upper switching element 212 and the lower switching element 214 across a variety of operating temperatures.
As shown in
As shown in
To reduce a switching performance parameter such as voltage oscillation magnitude of the upper switching element 212, the resistance of the turn on resistor can be decreased from 4.5 ohms to a smaller value to get improved switching performance for both the upper switching element 212 and the lower switching element 214. For example,
This gate resistor design can also be suitable for the lower switching element 214 in limited operating conditions. For instance,
However, when the test temperature is increased from 25° C. to 125° C., the switching performance of the lower switching element 214 with the second gate resistor network design can be diminished. For instance,
As illustrated by the above example, different gate resistor designs for the upper switching element 212 and the lower switching element 214 lead to improved switching performance (e.g. reduced voltage oscillations) for both the upper switching element 212 and the lower switching element 214 across a wide range of operating conditions, such as across operating temperatures from 25° C. to 125° C. In particular, a gate resistor design that includes a turn on resistor of 1.95 ohms and a turn off resistor of 28 ohms can provide improved switching performance (e.g. reduced voltage oscillations) for an upper switching element 212 of a Fuji 6MBI450U4-120 switching module. A gate resistor design that includes a turn on resistor of 4.5 ohms and a turn off resistor of 28 ohms can provide improved switching performance (e.g. reduced voltage oscillations) for a lower switching element 214 of a Fuji 6MBI450U4-120 switching module. In accordance with aspects of the present disclosure, these different gate resistor networks can be provided on the same gate circuit card to provide improved output power capability of a power converter.
Different gate resistor networks can also be suitable for switching modules made by different manufacturers. For instance, as shown in
For instance,
The third gate resistor network 280 can include a third turn on resistor 282 and a third turn off resistor 284. The fourth gate resistor network 290 can include a fourth turn on resistor 292 and a fourth turn off resistor 294. Characteristics of the third gate resistor network 280 and the fourth gate resistor network 290 can be different from characteristics of the first gate resistor network 250 and the second gate resistor network 260 of the gate circuit 240 associated with switching module 210. For instance, the third turn on resistor 282 can have a resistance that is different from the resistance of the first turn on resistor 252. Alternatively or in addition, the fourth turn on resistor 292 can have a resistance that is different from the resistance of the second turn on resistor 262.
Similar to the gate circuit 240, characteristics of the third gate resistor network 280 can be selected to be different from characteristics of the fourth gate resistor network 290 to improve the switching performance of both the upper switching element 212 and the lower switching element 214. More particularly, the third turn on resistor 282 of the third gate resistor network 280 can have a resistance that is different from a resistance of the fourth turn on resistor 292 of the fourth gate resistor network 290. Alternatively or in addition, the third turn off resistor 284 of the third gate resistor network 280 can have a resistance that is different from a resistance of the fourth turn off resistor 294 of the fourth gate resistor network 290.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/CN2012/074578 | 4/24/2012 | WO | 00 | 8/28/2014 |
