The present application relates to multi-phase-shift control of a power converter, and more particularly a power converter for an electric vehicle.
Conventional electric vehicles utilize a power converter, such as a DC/DC converter, for providing power to one or more vehicle components, including a vehicle battery. Many conventional electric vehicles plug-in into the electric grid for receiving power to charge the vehicle battery. The electrical grid typically provides single-phase or three-phase AC power. The electric vehicle may include charger circuitry that converts the AC power to DC power for charging the vehicle battery. This charger circuitry is typically described in the realm of battery electric vehicles as an on-board battery charger.
Conventional electric vehicle specifications call for high power densities for a variety of reasons, including large battery capacities, possibly 100 kWh, consumer desire for short charging times, and space constraints within the electric vehicle. Several conventional efforts have been made to comply with these requirements but with little success or at the cost of efficiency. These conventional efforts do not provide 1) zero voltage switching (ZVS) for all semiconductor switches within a wide-input-voltage range (e.g., 120-240 VAC) and a wide-output-voltage range (e.g., 200-450 VDC) and 2) high-performance at light load (i.e., they fail to maintain unity power factor at light load). In other words, these conventional efforts experience loss of performance when operated with wide voltage-gains and/or grid current distortion at light load conditions.
For instance, one conventional power converter for an on-board battery charger includes a dual-active-bridge (DAB) circuit that utilizes a single-phase-shift mode of operation. Traditionally, an uncontrolled (diode-based) AC to DC rectifier may be used to convert the AC grid input voltage into a (somewhat) constant DC input voltage for the primary-side DAB input. The DAB may include semiconductor switches that form an active H-bridge for controlling the voltage on the primary and secondary sides of a transformer. The primary-side H-bridge is used in converting a constant DC voltage or a low-frequency time-varying DC voltage into high-frequency AC voltage to drive the transformer and the secondary-side H-bridge is used in rectifying the high-frequency AC power transferred across the transformer back to DC. The single-phase-shift mode of operation may include shifting the phase of both secondary-side H-bridge legs relative to the two primary-side H-bridge legs in an effort to deliver power to the secondary side while achieving zero-voltage switching for all semiconductor switches—but may fail to do so under light loads. Another conventional power converter utilizes the DAB circuity topology but operates it by varying both switching frequency and phase shift. This alternative conventional configuration may ensure ZVS over a wider voltage range, but may still sacrifice the light-load grid current performance or fail to provide unity power factor at the primary-side input. Accordingly, there remains a continued need for an improved power converter adapted to provide ZVS over a wide voltage range with high performance in light load conditions.
The present invention provides multi-phase-shift control of a power converter for converting a low-frequency time-varying DC input voltage into a constant DC output voltage. The multi-phase-shift control can generate two-level or three-level voltage waveforms on either/both the primary or/and secondary sides of the transformer to yield a system which ensures zero-voltage switching and unity power factor over a wide range of input and output voltage levels and power throughputs, including low and high power outputs.
More specifically, in one embodiment, the power converter operates under a dual-phase-shift (DPS) control or in a triple-phase-shift (TPS) control. The primary and secondary sides are inductively coupled through the transformer. Thus, power can be transferred from the primary to the secondary by proper control of the multi-level voltage signals applied to both the primary and secondary windings of the transformer. The primary-side H-bridge can be controlled to supply power from the input side through generation of either a) a two-level voltage waveform, where the two primary-side H-bridge legs switch 180 degrees out of phase, or b) a three-level voltage waveform, where the two primary-side H-bridge legs switch at a phase shift between 0 and 180 degrees. The secondary-side H-bridge can also be controlled to deliver power to the output side through generation of either a) a two-level voltage waveform, or b) a three-level voltage waveform. When both sides employ a two-level voltage waveform, it is known as single-phase-shift (SPS) control. When the primary-side voltage is three-level and the secondary-side voltage is two-level, it is known as primary-dual-phase-shift (PDPS) control. When the primary-side voltage is two-level and the secondary-side voltage is three-level, it is known as secondary-dual-phase-shift (SDPS) control. Finally, when both the primary-side and secondary-side H-bridge voltages are three-level waveforms, it is known as triple-phase-shift (TPS) control.
The power converter also includes a control system coupled to the primary-side H-bridge and the secondary-side H-bridge. The control system is configured to control the primary-side H-bridge and the secondary-side H-bridge to operate differently during moments of high or low values of instantaneous power transfer. During high instantaneous powers, the control system may direct a) the primary-side H-bridge to generate a two-level voltage waveform or b) the secondary-side H-bridge to generate a two-level voltage waveform, while the other H-bridge still generates a three-level voltage waveform. In the low power mode, the control system may direct both the primary-side H-bridge and the secondary-side H-bridge to generate a three-level voltage waveform.
Before the embodiments of the invention are explained in detail, it is to be understood that the invention is not limited to the details of operation or to the details of construction and the arrangement of the components set forth in the following description or illustrated in the drawings. The invention may be implemented in various other embodiments and of being practiced or being carried out in alternative ways not expressly disclosed herein. Also, it is to be understood that the phraseology and terminology used herein are for the purpose of description and should not be regarded as limiting. The use of “including” and “comprising” and variations thereof is meant to encompass the items listed thereafter and equivalents thereof as well as additional items and equivalents thereof. Further, enumeration may be used in the description of various embodiments. Unless otherwise expressly stated, the use of enumeration should not be construed as limiting the invention to any specific order or number of components. Nor should the use of enumeration be construed as excluding from the scope of the invention any additional steps or components that might be combined with or into the enumerated steps or components.
A power converter in accordance with one embodiment of the present disclosure is shown in
In the illustrated embodiment, the controller 102 is isolated from the secondary-side H-bridge 108 such that control over the secondary-side H-bridge 108 is effected through control signals communicated in a galvanically isolated manner (e.g., opto-isolators). It should be understood that, in one embodiment, the controller 102 may be directly coupled to the secondary-side H-bridge 108 to direct switching operation thereof.
The power converter 100 is coupled to a battery 110, directly or indirectly via a charging control circuit (not shown). The battery 110 and the power converter 100 are incorporated into a vehicle in the present embodiment, however, it should be understood that the present disclosure is not limited to the realm of vehicles or battery charging. The power converter 100 can be utilized in a wide variety of applications outside the realm of vehicles, and can be utilized in connection with any type of load, including a load other than the battery 110.
Referring again to
The primary-side H-bridge 104 includes four primary-side switches P1, P2, P3, P4, two of which are high-side switches and two of which are low-side switches. The primary-side switches may be conventional Silicon MOSFETs, or they may be wide-bandgap (WBG) devices, such as Silicon Carbide (SiC) MOSFETs or Gallium Nitride (GaN) HEMTs. Other WPG devices can include silicon nitride devices, boron nitride devices, aluminum nitride devices, and semiconductor devices with diamond material. These primary-side-switches P1-P4 are controlled by the controller 102 to energize the primary of the transformer 106 with power from the DC input in accordance with one or more embodiments herein. In the illustrated embodiment, the primary-side H-bridge 104 is coupled to the primary winding of the transformer 106 via an inductor 121. In another embodiment, the leakage inductance of transformer 106 may also be used to facilitate the magnetic energy storage of inductor 121, in which case, the primary-side H-bridge 104 may be directly connected to the primary winding of the transformer 106.
The secondary-side H-bridge 108 includes four secondary-side switches S1, S2, S3, S4. As discussed herein, the controller 102 directs operation of the secondary-side switches S1-S4 to condition power received in the secondary of the transformer 106 to yield the DC output voltage or Vo. In the illustrated embodiment, the secondary-side H-bridge 108 is coupled to a filter capacitor 122 in addition to a load, such as the battery 110.
I. Overview
In one embodiment, the primary-side H-bridge 104, transformer 106, and the secondary-side H-bridge 108 form a dual-active-bridge (DAB) stage. This DAB stage is controllable according to one or more methodologies herein to yield zero voltage switching on all semiconductor switches and unity power factor at low and high power outputs.
More specifically, in one embodiment, the controller 102 operates the DAB stage in a dual-phase-shift mode or a triple-phase-shift mode. In the dual-phase-shift mode, the controller 102 operates the DAB stage so that either the primary-side H-bridge 104 or the secondary-side H-bridge 108 generates a two-level voltage signal in the transformer 106, and the other of the primary-side H-bridge 104 and the secondary-side H-bridge 108 generates a three-level voltage signal in the transformer 106. In multi-phase-shift control, the controller 102 periodically switches between both the dual-phase-shift mode and the triple-phase-shift mode. These variations can be seen in the experimental waveforms of
In one embodiment, the dual-phase-shift mode includes a variable-switching-frequency (VSF) dual-phase-shift (DPS) mode of operation and the triple-phase-shift mode includes a constant-switching-frequency (CSF) mode or a variable-switching-frequency (VSF) mode of operation. Operation according to both the dual-phase-shift mode and the triple-phase-shift mode, depending on one or more sensed characteristics, may yield a multiple-phase-shift (MPS) mode of operation. In another embodiment, with this type of MPS mode of operation, the power converter 100 may 1) realize ZVS turn-on for all switches within a wide-input range (e.g., 120-240 VAC, from 0 V to the peak grid voltage) and a wide-output range (e.g., 200-450 VDC) at the DAB stage, and 2) substantially ensure high-performance at light-load, i.e., maintaining low grid current distortion (unity PF). The VSF-DPS algorithm may secure ZVS, however its PF performance can deteriorate at light-loads. The MPS control algorithm may avoid the light-load grid-current distortion by evolving the VSF-DPS control to a subset of a triple-phase-shift (TPS) control. In this way, unconditional ZVS turn-on and unity power factor at light load is realized.
II. Dual-Phase-Shift Mode of Operation
The dual-phase-shift mode of operation in one embodiment corresponds to a type of control that includes operating the primary-side H-bridge 104 and the secondary-side H-bridge 108 to yield a) a two-level voltage signal on the primary and a three-level voltage signal on the secondary or b) a three-level signal on the primary and a two-level voltage signal on the secondary. These two types of operation may be characterized respectively as secondary-side DPS control (SDPS) or primary-side DPS control (PDPS), each being discussed below.
A. SDPS Control:
|vi(t)|<nVo
The operative timing of the primary-side switches P1-P4 and the secondary-side switches S1-S4 in accordance with the SPDS mode of control is show in the illustrated embodiment of
B. PDPS Control:
|vi(t)|>nVo
The operative timing of the primary-side switches P1-P4 and the secondary-side switches S1-S4 in accordance with the PDPS mode of control is show in the illustrated embodiment of
III. Triple-Phase-Shift Mode of Operation
The triple-phase-shift mode of operation in one embodiment corresponds to controlling the primary-side H-bridge 104 and the secondary-side H-bridge 108 to yield a three-level voltage signal on the primary of the transformer and a three-level voltage signal on the secondary of the transformer. This type of operation enhances light-load control capability and can yield near-unity power factor under light load conditions while maintaining ZVS down to zero power.
The operative timing of the primary-side switches P1-P4 and the secondary-side switches S1-S4 according to two types of TPS control are shown in the illustrated embodiments of
The transformer voltages and current are shown in
To realize ZVS turn-on during the switching of P1, P2, S3, and S4, the magnitude of Ir is selected to be sufficient enough to completely discharge the drain-source capacitances of the upper and lower switching devices during dead-time. ZVS turn-on of the other four switching events (P3, P4, S1, and S2) may be substantially guaranteed since the transformer current will be larger than Ir. The value Ip is the peak transformer current magnitude during the primary active-power-transfer interval when vp≠0 & vs=0. Similarly, Is the peak current magnitude of the secondary active-power-transfer interval when vs≠0 and vp=0. To substantially ensure that the value of Ir remains constant at the P1, S4, P2, and S3 turn-on points (and that the iL waveform is balanced), the two active-time intervals are determined as proportional to the primary and secondary-side voltages. The power transfer of the DAB operating under TPS control in the non-overlap case can be described as:
p(t)=nVo(Ir+Is)tsƒs,
which, after substituting and rearranging, yields the following:
This expression for power is a quadratic function of the secondary active-time interval, ts. We could also rewrite this power expression in terms of tp and |vi|.
While the output power depends on Ir, ƒs, tp, and ts, the value of Ir is independently controlled by only tr, the voltage magnitudes, and leakage inductance, L. Thus, Ir could be set to a constant desired value, determined by the switching device's output capacitance and maximum voltage while the power can be set by varying either ƒs and/or the time intervals. Here, the ZVS condition may be completely decoupled from the power delivery, unlike DPS control. Thus, from a control-standpoint, there is no significant need to vary ƒs; this will vary the width of the to inactive region of the switching waveform. This mode of operation may resolve the PF distortion problem of VSF DPS control at light loads.
One main limitation of non-overlap TPS is the maximum power transfer can be quite low for practical system parameter and voltage values. Additionally, the efficiency of non-overlap TPS will be quite low, since a majority of the transformer current is circulating during the inactive period, to, possibly leading to excessive conduction losses. For larger power transfer under TPS, both time intervals tp and ts may be made larger, such that ϕp>ϕs. In this condition, both voltages are non-zero for three time intervals: the overlap, active, and reactive intervals with power transfer described as:
p(t)=nVoƒs[(Ir+Is)ts+(Ip+Is)tov],
which after substation and rearrangement yields:
This power expression is also a quadratic function of the total active time interval (tp+tov in this case). Also, note that the sign on the 2nd-order term is negative, indicating that there exists a maximum-power-point achievable with this control. If the switching frequency is lowered under TPS control, it is possible to increase the maximum power point, Pmax, to any arbitrary value (within reasonable system limitations).
It therefore is possible to utilize a VSF TPS control to cover the entire power range. However, one downside with such a scheme is that the circulating current and peak switching currents can become quite large with lower frequencies. Lowering the frequency in the non-overlap region may increase the to time interval in
IV. MPS Control—Dual and Triple Phase Shift Modes
As noted above, MPS control of the power converter is achieved with a combination of any two or more of the following modes of control: SPS, primary-side DPS, secondary-side DPS, and TPS. The following Table 1 depicts each mode of control and the corresponding waveforms for both the primary voltage and the secondary voltage. Of note, SPS may be used in conjunction with MPS control, but only under limited circumstances.
Further by example, the controller 102 in one embodiment operates according to an MPS mode of operation that utilizes both the dual-phase-shift mode of operation and the triple-phase-shift mode of operation. The determination of whether to switch from the dual-phase-shift mode of operation or the triple-phase-shift mode of operation is based on the amount of power being consumed. The controller 102 is coupled to one or more sensors of the power converter 100 configured to sense one or more characteristics of power in the power converter 100. Based on the one or more sensed characteristics, the controller 102 may determine to operate according to the dual-phase-shift mode or the triple-phase-shift mode. In one embodiment, the controller 102 may determine to operate in the triple-phase-shift mode based on the one or more sensed characteristics indicating low power consumption, and to operate in the dual-phase-shift mode based on the one or more sensed characteristics indicating high power consumption. Examples of the change from the triple-phase-shift mode to the dual-phase-shift mode are depicted in the illustrated embodiments of
The MPS control methodology resolves the complexity and PF distortion of the PDPS+SDPS control and the low efficiency of TPS control. The MPS control methodology in one embodiment may include operation according to high-frequency TPS control (primary and secondary as three-level) and VSF DPS control (primary or secondary as two-level and the other as three-level). The determination to switch or shift between TPS mode and the DPS mode may be based on one or more sensed characteristics and/or one or more operating parameters. For instance, at a given switching frequency, the controller 102 may calculate the expected output power under both control schemes (e.g., a power value). The transition point may occur when those power values are equal or very close to equal. The controller 102 may determine this equality and control the operation to change modes at or near the transition point, which is where the power levels are close to equal, resulting in substantially low or no distortion.
In the illustrated embodiment of
In MPS, the TPS non-overlap and some of the TPS overlap control ranges may be used during low instantaneous power output intervals. When the instantaneous power demand is approximately equal to the TPS/DPS equal-power-point and is increasing, the controller 102 may phase-jump from the left-side power-point to the right-side power-point in
This type of control may be visualized in the simulation waveform of
The MPS control according to one embodiment may yield the following: (1) with low instantaneous power, the DAB operates using TPS on the left-side of the power curve in
As used herein, “two-level voltage waveform” or “two-level voltage signal” means an AC step voltage that alternates between a maximum value and a minimum value, with no intermediate step voltage therebetween, an example being shown in
The above description is that of current embodiments of the invention. Various alterations and changes can be made without departing from the spirit and broader aspects of the invention. This disclosure is presented for illustrative purposes and should not be interpreted as an exhaustive description of all embodiments of the invention or to limit the scope of the claims to the specific elements illustrated or described in connection with these embodiments. Any reference to elements in the singular, for example, using the articles “a,” “an,” “the,” or “said,” is not to be construed as limiting the element to the singular.
This application claims the benefit of U.S. Provisional Application 62/565,429, filed Sep. 29, 2017, the disclosure of which is incorporated by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2018/057561 | 9/28/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/064259 | 4/4/2019 | WO | A |
Number | Name | Date | Kind |
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8817507 | Liu | Aug 2014 | B2 |
20100097031 | King | Apr 2010 | A1 |
20140368167 | Okura | Dec 2014 | A1 |
Entry |
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Krismer, Florian, and Johann W. Kolar. “Efficiency-optimized high-current dual active bridge converter for automotive applications.” IEEE Transactions on Industrial Electronics 59.7 (2011): 2745-2760. |
International Search Report and Written Opinion of International Application PCT/IB2018/057561 dated Nov. 27, 2018. |
Number | Date | Country | |
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20200266714 A1 | Aug 2020 | US |
Number | Date | Country | |
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62565429 | Sep 2017 | US |