Patent Application
20250226748
This non-provisional application claims priority under 35 U.S.C. § 119(a) on Patent Application 202410027369.5 filed in P.R. China on Jan. 8, 2024, the entire contents of which are hereby incorporated by reference.
Some references, if any, which may include patents, patent applications and various publications, may be cited and discussed in the description of this application. The citation and/or discussion of such references, if any, is provided merely to clarify the description of the present application and is not an admission that any such reference is “prior art” to the application described herein. All references listed, cited and/or discussed in this specification are incorporated herein by reference in their entireties and to the same extent as if each reference was individually incorporated by reference.
The invention relates to the technical field of black start of the circuit, and
particularly to a bidirectional DC/DC converter, an energy storage device and a control method thereof.
Self-recovery of the system after power failure of the grid at a large area is generally referred to black start. When the system is all power failure, the entire system is shut down due to fault and is in a full “black” state. When the system needs to start, the equipment having self-start capability in the system firstly start, and then drive operation of the equipment having no self-start capability, thereby gradually expanding a recovery range of the system. And finally achieve recovery of the entire system without assistance of other devices.
In an energy storage system where batteries are directly connected to a power control system (PCS), the black start function is implemented by a black start mode of the PCS. However, in order to optimize performance of the batteries, improve service life of the batteries and enhance adaptability of connecting different batches and different types of batteries, single cluster charge and discharge management on the batteries shall be made, so the energy storage system shall add a DC/DC module at a battery side.
There are two structures to add the DC/DC module at the battery side. The first structure is that a part of batteries in the system are configured with the DC/DC modules and the other part of batteries are directly connected to the DC bus. When black starting, the DC bus voltage is supplied using a direct-mounted battery, then the DC/DC module is started to control the DC bus voltage, and next black start of the system is completed through the PCS.
The second structure is that all batteries in the system are configured with the DC/DC modules. When black starting, a self-start DC load equipment is disconnected firstly, then the DC bus capacitor is precharged via antiparallel diodes of the DC/DC module and a precharging resistor R, next the DC/DC module is started to control the DC bus voltage, and black start of the system is completed using the PCS after the DC Load is connected. Since the existing DC/DC module itself does not have black start capability, the second structure shall perform the black start operation from a system level, additional large power precharging resistors and high-voltage DC contactors are added, and complexity of the control logic is increased.
In conclusion, the existing DC converter has more issues when black starting, so it is necessary to make improvement.
With respect to the deficiencies, an object of the invention is to provide a bidirectional DC/DC converter having self-start capability and a flexible voltage soft start way, thereby optimizing system hardware topology of the energy storage device.
In order to achieve the object, the invention provides a bidirectional DC/DC converter. The bidirectional DC/DC converter includes a low-voltage port having a first voltage, a high-voltage port, a start circuit having one end electrically connected to the low-voltage port, an inductor having one end electrically connected to the other end of the start circuit, and a switch circuit having both ends electrically connected to the high-voltage port and the other end of the inductor, respectively. The start circuit includes at least one controllable switch. When the bidirectional DC/DC converter starts from the low-voltage port, a voltage of the high-voltage port is established using the first voltage, by controlling the at least one controllable switch.
Alternatively, the bidirectional DC/DC converter further includes a first capacitor connected in parallel to the high-voltage port, and a second capacitor connected in parallel to the low-voltage port, wherein the start circuit is electrically connected between the first capacitor and the inductor.
Alternatively, when the bidirectional DC/DC converter starts from the low-voltage port, the voltage of the high-voltage port increases from zero to the first voltage, and a slope of voltage change is controlled based on a duty ratio of the at least one controllable switch.
Alternatively, the duty ratio of the at least one controllable switch is controlled to gradually increase, thereby gradually increasing the voltage of the high-voltage port to the first voltage.
Alternatively, when the bidirectional DC/DC converter starts from the low-voltage port, the bidirectional DC/DC converter enters a first working stage. At the first working stage, the start circuit and the inductor perform buck conversion on the first voltage to obtain the voltage of the high-voltage port, and the switch circuit works in a constant conduction mode to provide current paths between the high-voltage port and the power conversion circuit.
Alternatively, the bidirectional DC/DC converter enters a second working stage when the first working stage ends. At the second working stage, the switch circuit and the inductor perform boost conversion on the first voltage to obtain the voltage of the high-voltage port; and the start circuit works in the constant conduction mode to provide current paths between the low-voltage port and the second power conversion circuit.
Alternatively, at the first working stage, the voltage of the high-voltage port is increased from 0 to the first voltage; and at the second working stage, the voltage of the high-voltage port is increased from the first voltage to a target voltage.
Alternatively, the start circuit includes a main switching tube electrically connected between a first end of the low-voltage port and the inductor, and an auxiliary switching tube having one end electrically connected to a connection point of the main switching tube and the inductor, and the other end electrically connected to a second end of the low-voltage port.
Alternatively, the start circuit further includes a short-circuit switch electrically connected in parallel to the main switching tube. When the main switching tube is conducted constantly, the short-circuit switch is closed.
Alternatively, at the first working stage, a duty ratio of the main switching tube is controlled to gradually increase and the voltage of the high-voltage port is gradually established to the first voltage; and at the second working stage, the main switching tube is controlled to conduct constantly.
Alternatively, the switch circuit is a first flying capacitor switch circuit, and includes a first switching tube, a second switching tube, a third switching tube, a fourth switching tube, and a first flying capacitor. The first switching tube, the second switching tube, the third switching tube and the fourth switching tube are connected in series. The first flying capacitor has one end electrically connected between the first switching tube and the second switching tube, and the other end electrically connected between the third switching tube and the fourth switching tube. And a first end of the first switching tube and a second end of the fourth switching tube are connected in parallel to the high-voltage port.
Alternatively, the first voltage is greater than or equal to one half of the target voltage. At the first working stage, the second switching tube and the fourth switching tube are conducted to charge the first flying capacitor, and the second switching tube and the fourth switching tube are turned off when a voltage of the first flying capacitor is equal to one half of the target voltage.
Alternatively, the first voltage is less than one half of the target voltage. At the first working stage, the second switching tube and the fourth switching tube are conducted constantly to charge the first flying capacitor.
Alternatively, the start circuit is a second flying capacitor switch circuit, and includes a fifth switching tube, a sixth switching tube, a seventh switching tube, an eighth switching tube, a first resistor, a second resistor, a third resistor, a fourth resistor and a second flying capacitor. The fifth switching tube, the sixth switching tube, the seventh switching tube and the eighth switching tube are sequentially connected in series. A first end of the fifth switching tube is electrically connected to a first end of the low-voltage port, and a second end of the eighth switching tube is electrically connected to a second end of the low-voltage port. A second end of the sixth switching tube is electrically connected to the inductor. The second flying capacitor is electrically connected between a first end of the sixth switching tube and a second end of the seventh switching tube. The first resistor, the second resistor, the third resistor and the fourth resistor are sequentially connected in series, the first resistor is connected in parallel to the fifth switching tube, a first end of the second resistor and a second end of the third resistor are connected in parallel to the second flying capacitor, and the fourth resistor is connected in parallel to the eighth switching tube.
Alternatively, at the first working stage, pulse widths of switching signals of the fifth switching tube and the sixth switching tube are controlled to gradually increase, and pulse widths of switching signals of the seventh switching tube and the eighth switching tube are controlled to gradually decrease. And at the second working stage, the fifth switching tube and the sixth switching tube are conducted constantly, and the seventh switching tube and the eighth switching tube are off.
The invention further provides an energy storage device. The energy storage device includes a power condition system, a DC bus electrically connected to a DC side of the power condition system, multiple energy storage units, each electrically connected to the DC bus through a bidirectional DC/DC converter. At least one bidirectional DC/DC converter includes a low-voltage port having a first voltage supplied by a corresponding energy storage unit; [a high-voltage port electrically connected to the DC bus; a start circuit having one end electrically connected to the low-voltage port, wherein the start circuit includes at least one controllable switch; an inductor having one end electrically connected to the other end of the start circuit; and a switch circuit having both ends electrically connected to the high-voltage port and the other end of the inductor, respectively. When the at least one bidirectional DC/DC converter starts from the low-voltage port, a voltage of the high-voltage port is established using the first voltage, by controlling the at least one controllable switch.
Alternatively, the energy storage device is electrically connected to a power supply system, and when the power supply system loses power, the energy storage units output power to the at least one bidirectional DC/DC converter and establish a bus voltage through the at least one bidirectional DC/DC converter.
Alternatively, when the bidirectional DC/DC converter starts from the low-voltage port, the voltage of the high-voltage port increases from zero to the first voltage, and a slope of voltage change is controlled based on a duty ratio of the at least one controllable switch.
Alternatively, when the at least one bidirectional DC/DC converter starts from the low-voltage port, the start circuit and the inductor perform buck conversion on the first voltage and establish the voltage of the high-voltage port to the first voltage; and the switch circuit and the inductor perform boost conversion on the first voltage and establish the voltage of the high-voltage port from the first voltage to the second voltage.
Alternatively, when the start circuit and the inductor perform buck conversion, the switch circuit works in a constant conduction mode to provide current paths between the high-voltage port and the start circuit; and when the switch circuit and the inductor perform boost conversion, the start circuit works in the constant conduction mode to provide current paths between the low-voltage port and the switch circuit.
The invention further provides a method of controlling a bidirectional DC/DC converter. The bidirectional DC/DC converter includes a low-voltage port having a first voltage; a high-voltage port; a start circuit having one end electrically connected to the low-voltage port; an inductor having one end electrically connected to the other end of the start circuit; and a switch circuit having both ends electrically connected to the high-voltage port and the other end of the inductor, respectively. When the bidirectional DC/DC converter starts from the low-voltage port, the control method includes:
To make the object, technical solution and advantage of the invention clearer, hereinafter the invention is further explained in details with reference to the accompanying drawings and the embodiments. It shall be understood that the described specific embodiments are only to explain the invention, but not limited to the invention.
It shall be noted that references of “one embodiment”, “embodiments” and “exemplary embodiments” in the specification refer to that the described embodiment may include specific features, structures or properties, but it is not that every embodiment must include these specific features, structures or properties. Moreover, such expression does not refer to the same embodiment. Further, when the specific features, structures or properties are described with reference to the embodiments, regardless of clear description, it has indicated that such feature, structure or property combined in other embodiments is within the knowledge range of those skilled in the art.
Moreover, the specification and subsequent claims use some phrases to refer to specific components or members, and those ordinary in the art shall understand that manufacturers may name the same component or member using different nouns or terms. The specification and subsequent claims do not use the difference of names as the way of distinguishing the component or member, but using the difference of functions of the component or member as the distinguishing criterion. “comprise” and “include” mentioned in the whole specification and subsequent claims are open words, so they shall be understood to be “include but not limited to”. Moreover, the word “connection” includes any direct or indirect electrical connection means. Indirect electrical connection means includes connecting through other devices.
The intermittent power generation features of clean energy bring a certain challenge to safe and stable operation of the grid. Energy storage technology serves as an effective measure to suppress power fluctuation of the grid and enhance quality of electric energy, and is applied to power generation system of the clean energy.
The energy storage system is connected to the grid, and takes the common DC bus as an energy transfer carrier. The constant control of the DC bus voltage decides operation modes of the devices in the energy storage system. As a core device of energy conversion of the energy storage system, the bidirectional DC/DC converter adjusts flow of energy between the DC bus and the battery unit to realize stabilizing balanced control of the bus voltage and the battery according to a voltage value.
In the system, the bidirectional DC/DC converter has various working modes, works in a buck mode, and can also work in a boost mode to satisfy a wide variation range of a voltage of the battery unit and the DC bus voltage. To improve energy conversion efficiency, a non-isolated topology is often used, such as a two-level topology, a three-level topology and a cascaded multi-level topology. When the system black starts, the DC bus shall begin to establish the bus voltage from 0V through the bidirectional DC/DC converter. However, due to existence of a mF-level capacitive load, some devices that detect the bus voltage and self-start on the DC bus, and the inherent antiparallel diodes in the topologies, an uncontrollable energy flow path exists from the battery side to a DC bus side. When a voltage at the bus side is lower than a voltage at the battery side, a current of the flow path shall be controlled, thereby ensuring to suppress a surge current on the premise of establishing the voltage, and protecting the switching tubes from not being damaged. When a self-start DC load equipment is connected on the DC bus, it will start when the bus reaches a threshold voltage, thereby lowering the DC bus voltage. If the DC load requires a large power, the precharge circuit cannot control the voltage of the high-voltage port to reach a target value. Therefore, a capacitance of the capacitive load, the consumed power of the self-start device, and the like bring a strong coupling constraint design to selection of a power and a resistance of a resistor in the precharge circuit. So the precharge resistance and power shall be adjusted and adapted according to configurations of the system. In conclusion, the resistor precharge circuit has limits and couplings from multiple aspects. After the energy storage system adds the bidirectional DC/DC converter module, usability of the system is reduced, and additional control means shall be added.
The invention provides an improved bidirectional DC/DC converter.
In this embodiment, the voltage of the low-voltage port PortB is supplied by a DC source, and is corresponding to a first voltage Lv. When starting from the low-voltage port, the voltage of the high-voltage port PortA is an output voltage of the bidirectional DC/DC converter. The voltage of the high-voltage port PortA is increased from zero to a target voltage, and the target voltage corresponds to a second voltage Hv.
The start circuit A1 has a first end electrically connected to the low-voltage port PortB and a second end electrically connected to a first end of the inductor L1, and includes at least one controllable switch. When the bidirectional DC/DC converter starts from the low-voltage port, the start circuit A1 is configured to establish the voltage of the high-voltage port through the voltage of the low-voltage port. The start circuit A1 of the bidirectional DC/DC converter provided in this embodiment performs buck conversion on the voltage of the low-voltage port to stably establish the voltage of the high-voltage port to the first voltage Lv. The voltage of the high-voltage port will not be lowered by a mF-level capacitor and self-start devices on the DC bus. PWM modulation is performed to the at least one controllable switch in the start circuit A1, such that the voltage of the high-voltage port is flexibly controllable during establishment from 0 to the first voltage Lv.
The switch circuit A2 has a first end electrically connected to a second end of the inductor L1, and a second end electrically connected to the high-voltage port PortA. After the voltage of the high-voltage port is stably established to the first voltage Lv, PWM modulation is performed on the switch circuit A2 and the switch circuit A2 performs boost conversion on the voltage of the low-voltage port to stably establish the voltage of the high-voltage port to the second voltage Hv. In actual application, the line has an impedance, and the diode also has a voltage drop, so “equal to”, “stabilize”, “approach”, “substantially stabilize”, “substantially equal to”, “establish to”, or the like in the disclosure allows an error, for example, +/−10%, preferably, +/−5%.
The voltage of the high-voltage port increases from zero to the first voltage Lv to form a voltage change curve. A slope of the voltage change curve is controlled by adjusting a duty ratio of the at least one controllable switch. For example, the duty ratio of the at least one controllable switch is adjusted by closed loop control. As compared to start through the precharge resistor, a voltage controllable range of the high-voltage port PortA is expanded by using the start circuit A1, such that a theoretical control range of the voltage of the high-voltage port PortA is increased from [Lv, Hv] to [0, Hv]. The soft-start establishment of the voltage of the high-voltage port PortA can be realized from 0V to a target voltage. A voltage control dead zone of the high-voltage port PortA [0, Lv] is eliminated, and the voltage of the high-voltage port PortA is continuously controllable. The soft-start process of the high-voltage port PortA corresponds to gradually establishing the voltage of the high-voltage port PortA to the first voltage Lv by controlling a duty ratio of the at least one controllable switch to gradually increase. With respect to the control technique of the controllable switch, please refer to the existing voltage modulation technique, and the details are not described here.
When starting from the low-voltage port, working stages of the bidirectional DC/DC converter in this embodiment include a first working stage and a second working stage. At the first working stage, the start circuit A1 and the inductor L1 perform buck conversion on the first voltage Lv to obtain the voltage of the high-voltage port. That is to say the start circuit A1 and the inductor L1 serve as a power conversion circuit to convert the first voltage Lv and establish the voltage of the high-voltage port. And at the first working stage, the voltage of the high-voltage port can be gradually increased to the first voltage Lv. A duty ratio within the start circuit A1 is gradually increased such that the voltage of the high-voltage port PortA can be slowly increased from 0V to avoid generating a surge impulse current. The duty ratio of the start circuit A1 is closed-loop modulated to stabilize the voltage of the high-voltage port to a set value without fluctuation due to the mF-level capacitor and/or the self-start devices on the DC bus. When the voltage of the high-voltage port PortA is stably increased to the first voltage Lv, the second working stage is entered. The switch circuit A2 and the inductor L1 form a second power conversion circuit which performs boost conversion on the first voltage Lv to obtain the voltage of the high-voltage port, such that the voltage of the high-voltage port PortA is gradually increased from the first voltage Lv to the second voltage Hv.
When the bidirectional DC/DC converter starts from the low-voltage port PortB, PWM modulation is performed on the start circuit A1 to establish the voltage of the high-voltage port PortA to a first target value (such as, the voltage Lv), and then PWM modulation is performed on the switch circuit A2 to establish the voltage of the high-voltage port PortA to a second target value (such as, the voltage Hv). In the start process, the voltage of the high-voltage port PortA is controllable in a range [0, Hv], the time and the soft start way of establishing the voltage of the high-voltage port PortA are flexibly controllable. And coupling parameters such as a capacitor capacity of the DC bus, a bus mounting load and a precharge resistor R21, and the like are decoupled.
At the first working stage, the switch circuit A2 works in a constant conduction mode to provide current paths between the high-voltage port and the first power conversion circuit. The constant conduction mode can be understood that at the first working stage, the switch circuit A2 always has at least one conducting branch, such that a current of the start circuit A1 flows the at least one conducting branch into the high-voltage port. For example, a part or all switches in the conducting branch are turned on constantly.
At the second working stage, the start circuit A1 works in the constant conduction mode to provide current paths between the low-voltage port and the second power conversion circuit. The constant conduction mode can be understood that at the second working stage, the start circuit A1 always has at least one conducting branch, such that a current of the low-voltage port PortB flows the at least one conducting branch into the switch circuit A2. For example, a part or all switches in the conducting branch are turned on constantly.
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At the first working stage, the PWM modulation is performed to control the main switching tube S5, a duty ratio of the main switching tube S5 is gradually increased, the buck circuit performs voltage conversion on the voltage Lv of the low-voltage port PortB, and an output of the buck circuit is gradually increased from 0 to the first voltage Lv. The switch circuit A2 works in the constant conduction mode. Specifically, the second switching tube S2 and the fourth switching tube S4 are controlled to conduct constantly to form a conducting branch, and the start circuit A1 charges the flying capacitor C2 through the conducting branch. The second switching tube S2 and the diode D1 form another conducting branch, the start circuit A1 charges the first capacitor C1 through the conducting branch, the first main switch K1 is closed, and the voltage of the high-voltage port PortA is gradually established. At the first working stage, the voltage of the high-voltage port PortA is established in the buck mode of the start circuit A1. In the process, a PWM pulse signal of the main switching tube S5 is modulated to realize the soft-start of the high-voltage port PortA, thereby avoiding impulse of the surge current.
At the second working stage, the main switching tube S5 is controlled to conduct constantly. For example, a duty ratio of the main switching tube S5 is equal to 1. At this time, the start circuit A1 works in the constant conduction mode to provide a current path between the low-voltage port PortB and the second conversion circuit. At the second working stage, the PWM modulation is performed on the switching tubes S1 to S4 of the switch circuit A2, the second conversion circuit performs voltage conversion on the voltage Lv of the low-voltage port PortB, and an output of the second conversion circuit charges the first capacitor C1 and establish the voltage of the high-voltage port PortA. At the second working stage, the voltage of the high-voltage port PortA is established in the boost mode of the switch circuit A2, and the voltage of the high-voltage port PortA is increased from the first voltage Lv to the second voltage Hv.
At the first working stage, when the start circuit A1 and the inductor establish the voltage of the high-voltage port, the switch circuit A2 is in the conducting state. In a topological structure of the switch circuit A2, in order to avoid electronic components from being damaged, a voltage of the first flying capacitor C2 shall be ensured not to exceed one half of the second voltage Hv. Therefore, when the first voltage Lv is greater than or equal to one half of the second voltage Hv, the first working stage further includes controlling the second switching tube S2 and the fourth switching tube S4 to be on constantly to charge the first flying capacitor C2; and when the voltage of the first flying capacitor C2 is equal to one half of the second voltage Hv, controlling the second switching tube S2 and the fourth switching tube S4 to be turned off. At this time, the switch circuit A2 has a conducting branch formed of antiparallel diodes D1 and D2, and the start circuit A1 continues to charge the first capacitor C1 through the conducting branch to continue to establish the voltage of the high-voltage port PortA from 0.5 Hv to Lv. Since the maximum voltage of the first flying capacitor C2 is 0.5 Hv, when Lv≥0.5 Hv, at the first working stage, a path for charging the first flying capacitor C2 shall be cut off when the voltage of the first flying capacitor C2 reaches 0.5 Hv.
When the first voltage Lv is less than one half of the second voltage Hv, the first working stage controls the second switching tube S2 and the fourth switching tube S4 to be conducted constantly to charge the first flying capacitor C2. At this time, when the first working stage ends, the voltage of the first flying capacitor C2 is the first voltage Lv, and less than 0.5 Hv. So at the first working stage, the second switching tube S2 and the fourth switching tube S4 are not turned off in advance, and kept on to charge the first flying capacitor C2.
If the first voltage Lv is less than one half of the second voltage Hv, the second switching tube S2 and the fourth switching tube S4 are turned off after the first flying capacitor C2 is charged to the first voltage Lv. If the first voltage Lv is greater than or equal to one half of the second voltage Hv, the second switching tube S2 and the fourth switching tube S4 are turned off when the first flying capacitor C2 is charged to 0.5 Hv, and meanwhile, the voltage of the high-voltage port PortA continues to be charged to the first voltage Lv. After the first working stage ends, the second working stage is entered. And the main switching tube S5 of the start circuit A1 is turned on constantly, the first switching tube S1, the second switching tube S2, the third switching tube S3 and the fourth switching tube S4 of the switch circuit A2 are modulated in the closed-loop. In the second working stage, the voltage of the high-voltage port PortA is controllably established to the second voltage Hv, while the voltage of the first flying capacitor C2 is controlled to be 0.5 Hv. And when the voltage of the high-voltage port PortA is equal to the second voltage Hv, the start of the bidirectional DC/DC converter is completed.
When the voltage of the high-voltage port is established to the first voltage Lv, the main switching tube S5 is conducted constantly, and the auxiliary switching tube D6 is off.
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When the first voltage Lv is less than one half of the second voltage Hv, at the second working stage, the switch circuit A2 operates in the mode A, the mode B and the mode D.
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In some embodiments, the switch circuit A2 of the bidirectional DC/DC converter in any embodiment of
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In some embodiments, the switch circuit A2 and the inductors L11, L12 of the bidirectional DC/DC converter in any embodiment of
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Since the first voltage Lv is greater than or equal to one half of the second voltage Hv, the second switching tube S2 and the fourth switching tube S4 are turned off when the voltage of the first flying capacitor C2 is charged to one half of the second voltage Hv. And, operations and corresponding current loops of the start circuit A1 will change. Therefore, the first working stage of the bidirectional DC/DC converter in
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The invention further provides an energy storage device. The energy storage device includes a power condition system (PCS), a DC bus and multiple energy storage units. The DC bus is electrically connected to a DC side of the power condition system. Each of the multiple energy storage units is electrically connected to the DC bus through a bidirectional DC/DC converter, and at least one bidirectional DC/DC converter (such as, #1A and #20A) includes the low-voltage port, the high-voltage port, the start circuit, the inductor and the switch circuit. The energy storage units supply the first voltage to the corresponding low-voltage port of the DC/DC converter, the high-voltage port is electrically connected to the DC bus, and a target voltage of the high-voltage port is the second voltage. Further, the second voltage is equal to a voltage reference of the DC bus. One end of the start circuit is electrically connected to the low-voltage port, the start circuit includes at least one controllable switch, and one end of the inductor is electrically connected to the other end of the start circuit. Both ends of the switch circuit are electrically connected to the high-voltage port and the other end of the inductor, respectively. When starting from the low-voltage port, the at least one controllable switch is modulated, thereby using the first voltage to establish a voltage of the high-voltage port.
The energy storage device is electrically connected to a power supply system, such as, a grid. When the power supply system loses power, the energy storage units output energy to the at least one bidirectional DC/DC converter (such as, #1A and #20A) to establish a bus voltage through the at least one bidirectional DC/DC converter, thereby achieving the black start of the power condition system.
In some embodiments of the bidirectional DC/DC converter, the duty ratio of the at least one controllable switch in the start circuit is controlled through a closed loop method, thereby controlling the voltage of the high-voltage port to increase from zero to the first voltage Lv. A curve associated with the voltage change of the high-voltage port has a slope, and the slope is controlled based on the duty ratio of the at least one controllable switch. The process of establishing the voltage of the high-voltage port via the low-voltage port is flexibly controllable by modulating the duty ratio of the controllable switch of the start circuit.
When the bidirectional DC/DC converter starts from the low-voltage port, the start circuit performs buck conversion on the first voltage and establishes the voltage of the high-voltage port to the first voltage, and the switch circuit performs boost conversion on the first voltage and establishes the voltage of the high-voltage port from the first voltage to the second voltage. The second voltage is a target voltage of the DC bus.
When the start circuit performs buck conversion, the switch circuit works in a constant conduction mode to provide current paths between the high-voltage port and the start circuit. When the switch circuit performs boost conversion, the start circuit works in the constant conduction mode to provide current paths between the low-voltage port and the switch circuit.
The bidirectional DC/DC converter of the energy storage device has black start capability, and may establish the DC bus voltage without relying on other devices, thereby simplifying start flows of the energy storage system. Meanwhile, the bidirectional DC/DC converter has the capability of controlling the bus voltage when starting, so the devices connected to the DC bus have stronger adaptability. For example, a capacitive load with a large capacitance and a self-start load may be directly connected to the DC bus, and these loads can't cause start fail. The bidirectional DC/DC converter may control a voltage soft start slope and time, and the precharge circuit in the bidirectional DC/DC converter can be decoupled with the devices connected to the DC bus, thereby reducing the DC contactor, lowering the requirement for the precharge resistor, and reducing cost of the system.
The invention further provides a method of controlling a bidirectional DC/DC converter. The bidirectional DC/DC converter includes a low-voltage port, a high-voltage port, a start circuit and a switch circuit. The low-voltage port has a first voltage, and a target voltage of the high-voltage port is a second voltage. The start circuit has one end electrically connected to the low-voltage port. The inductor has one end electrically connected to the other end of the start circuit. The switch circuit has both ends electrically connected to the high-voltage port and the other end of the inductor, respectively.
When the bidirectional DC/DC converter starts from the low-voltage port, the control method includes: performing buck conversion on the first voltage through the start circuit to establish the voltage of the high-voltage port to the first voltage; and performing boost conversion on the first voltage through the switch circuit to establish the voltage of the high-voltage port from the first voltage to the second voltage. As for the control method and the achieved technical effect of the bidirectional DC/DC converter in this embodiment, reference may be made to the description of the corresponding parts of the bidirectional DC/DC converter in the above embodiments, and the details are not described here.
The bidirectional DC/DC converter of the invention has a self-start capability, and a flexibly controllable voltage soft start way. When the bidirectional DC/DC converter of the invention is configured in the energy storage system, coupling parameters such as capacitor capacity of the DC bus, bus mounting loads, precharge resistors, and the like may be decoupled to optimize system hardware topology.
Of course, the invention may further have various other embodiments, and without departing from spirit and essence of the invention, those skilled in the art shall make various corresponding modifications and variations according to the invention, but these corresponding modifications and variations shall belong to the protection scope of the appended claims of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202410027369.5 | Jan 2024 | CN | national |
