HYBRID PARTIAL POWER PROCESSING SYSTEM

Abstract

The hybrid partial power processing system includes differential power processing converters DPPs having low power ratings, which are used to exchange differential power between two adjacent PV modules, or between PV modules and a line capacitor (C.sub.lin) connected in series within the same string. The exchange of differential power by DPPs is needed to track the maximum power point of each PV module in the string. The DC power optimizing converter (DC-PO) is a DC/DC power converter used to feed current (power) from a PV module to C.sub.lin. The DC-PO is driven to track the maximum power point (MPP) of one PV module, and the MPP of each one of the remaining PV modules in the string is tracked by a DPP.

Claims

1. A hybrid partial power processing system, comprising: at least one DC power optimizing converter (DC-PO) having an input and an output, the converter output having first and second terminals; a photovoltaic (PV) module connected to the input of the DC-PO; a line capacitor having a downstream side and an upstream side, the downstream side being connected to the first output terminal of the DC-PO, the upstream side being connected to the second output terminal of the DC-PO; at least one downstream PV module connected in a serial string to the downstream side of the line capacitor; at least one upstream PV module connected in a serial string to the upstream side of the line capacitor; and for each of the at least one downstream and upstream PV modules, a corresponding differential power processing converter (DPP) having two differential leads connected in parallel across the PV module and a third lead connected to a neighboring PV module or the capacitor C.sub.lin; wherein the hybrid partial power processing system is configured to allow exchange of differential power between two adjacent PV modules or between a PV module and the line capacitor, thereby aiding speed of maximum power point tracking (MPPT) of the system.

2. The hybrid partial power processing system according to claim 1, wherein each of the DPP is selected from the group consisting of a bidirectional DPP and a unidirectional DPP.

3. The hybrid partial power processing system according to claim 1, wherein said at least one DC power optimizing converter (DC-PO) comprises a plurality of DC-POs connected across the line capacitor.

4. The hybrid partial power processing system according to claim 1, wherein the DPPs and said at least one DC-PO are selected from the group consisting of isolated converters or non-isolated converters.

5. The hybrid partial power processing system according to claim 1, wherein the DPPs and said at least one DC-PO comprise converters selected from the group consisting of buck DC/DC converters, boost DC/DC converters, buck-boost DC/DC converters, and resonant DC/DC converters.

6. The hybrid partial power processing system according to claim 1, wherein the two differential leads of said corresponding differential power processing converter (DPP) are connected across a plurality of the PV modules.

7. The hybrid partial power processing system according to claim 1, further comprising at least one power exchanging DC-DC converter connected in parallel with said at least one DC-PO.

8. The hybrid partial power processing system according to claim 1, wherein said corresponding differential power processing converter (DPP) includes a microcontroller using only local measurements of voltages and currents in said DPPs two ports to track the maximum power point (MPP) of the corresponding PV module for local control of the MPPT.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] FIG. 1 is a schematic diagram showing an exemplary hybridization of a PPP technique for processing partial power in a hybrid partial power processing system according to the present invention.

[0010] FIG. 2 is a schematic diagram of a generalized hybrid partial power processing system according to the present invention.

[0011] FIGS. 3A, 3B, 3C, 3D, and 3E are plots showing the output currents of first through fifth PV modules, respectively, in a simulation of a hybrid partial power processing system according to the present invention using a buck-boost type DC power optimizer (DC-PO).

[0012] FIGS. 4A, 4B, 4C, 4D, and 4E are plots showing the duty cycles for the differential power processing converters (DPPs) and DC-PO used in the buck-boost simulation of FIGS. 3A-3E.

[0013] FIGS. 5A, 5B, 5C, 5D, and 5E are plots showing the output currents of first through fifth PV modules, respectively, in a simulation of a hybrid partial power processing system according to the present invention using a buck-type DC power optimizer (DC-PO).

[0014] FIGS. 6A, 6B, 6C, 6D, and 6E are plots showing the duty cycles for the differential power processing converters (DPPs) and DC-PO used in the buck simulation of FIGS. 5A-5E.

[0015] Similar reference characters denote corresponding features consistently throughout the attached drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0016] As shown in FIG. 1, the hybrid partial power processing system (PPP hybridization 100a) includes differential power processing converter 106b (DPP.sub.n1) and differential power processing converter 106c (DPP.sub.n+1) where both of them have low rated power. The converters 106b and 106c are used to exchange the differential power of the PV module 102b (PV.sub.n1) and module 102c (PV.sub.n+1), respectively, with the line capacitor 110 (C.sub.lin). In one embodiment, the differential power processing converters 106b and 106c could be of bidirectional type where the power can flow in both directions. In other embodiments, the differential power processing converters 106b and 106c could be of unidirectional type, either feeding power to the line capacitor 110 (C.sub.lin) or extracting power from it. The DC power optimizing converter 104 (DC-PO) is a DC/DC converter used to feed current (power) from the PV module 101 (PV.sub.n1) to the line capacitor 110 (C.sub.lin). At least one power exchanging DC-DC converter may be connected in parallel with the DC-PO 104. Differential power processing converter 106b has one of its input/output ports connected across the terminals of PV module 102b (PV.sub.n+1), and the other port connected across the line capacitor 110. Similarly, differential power processing converter 106c has one port connected across the terminals (upstream and downstream) of the line capacitor 110. The other port of differential power processing converter 106c is connected across the terminals of PV module 102c (module PV.sub.n+1). It should be understood that the partial string comprises PV module 102b connected in series with line capacitor 110, which, in turn, is connected in series with PV module 102c. Most of the string current I.sub.str passes over the PV modules 102b, 102c, and the line capacitor 110, while a small portion of I.sub.str passes over DPPs 106b, 106c.

[0017] FIG. 2 shows the complete structure 100b of a PV string with the hybrid system for PPP (the PV modules 1021, 102a, 102b being connected in series and to the downstream side of the line capacitor C.sub.lin, and the PV modules 102c, 102d, and 102e being connected in series and to the upstream side of line capacitor C.sub.lin). The differential power processing converters 106b and 106c are connected to the string in the same manner as the DPP connections shown in FIG. 1, while each of the remaining differential power processing converters has PV modules connected in its two ports. E. g., the differential power processing converter 106a has the PV module 102a (PV.sub.n2) connected across one of its ports, while the other port is connected across the PV module 102b (PV.sub.n1). DPP.sub.1 1061, DPP.sub.n2 106a, DPP.sub.n1 106b, DPP.sub.n+1 106c, DPP.sub.n+1 106c and DPP.sub.Np 106e are shown to support bidirectional power flow, but unidirectional power flow operation could also be supported. The converter DC-PO 104 is a DC/DC converter used to feed current (power) from the module PV.sub.n 101 to C.sub.lin.

[0018] Let the maximum power point (MPP) currents for PV.sub.n1, PV.sub.n and PV.sub.n+1 in FIG. 1 be I.sub.m,n1, I.sub.m,n and I.sub.m,n+1, respectively. In general, the current I.sub.str that flows in the string could be different from I.sub.m,n1, I.sub.m,n and I.sub.m,n+1. Assume that:

I.sub.m,n1I.sub.str=I.sub.m,n1>0(1)

In this case, the converter DPP.sub.n1 106b can be driven such that the current I.sub.i,n1 shown in FIG. 1 becomes equal to I.sub.m,n1 in Equation (1). On the other hand, consider that:

I.sub.m,n+1I.sub.str=I.sub.m,n+1<0(2)

[0019] The converter DPP.sub.n+1 106c is then driven to track the MPP of PV.sub.n+1, which makes I.sub.i,n+1=I.sub.m,n+1. The converters DPP.sub.n1 106b and DPP.sub.n+1 106c process the currents I.sub.i,n1 and I.sub.i,n+1, respectively, and supply/draw appropriate currents to/from the capacitor C.sub.lin, whose values maintain balance between the converter input and output power. The output current of the converter DC-PO is driven independently to track the MPP of the module PV.sub.n. The gain of the converter DC-PO is automatically adjusted such that the sum of all currents of DPP.sub.n1, DPP.sub.n, DPP.sub.n+1 and DC-PO that flow to/from C.sub.lin becomes equal to the string current I.sub.str. The MPP of each PV is tracked independently by a separate DC/DC converter. Accordingly, fast maximum power point tracking (MPPT) of the individual PV modules could be achieved using only one DC-PO and low cost DPPs. DPPs have low cost and low losses, as they process only a fraction of the power produced by PV modules. Clearly, the MPPT could be achieved all the time, since whenever there is an increase in the PV power, the voltage across C.sub.lin will increase, and whenever there is a reduction in the PV power, a drop will occur in this voltage. The DC-PO always adjusts its duty ratio to track the MPP of PV.sub.n based on the voltage of C.sub.lin. Accordingly, low cost, high efficiency, modularity, simple control, simple structure, and fast MPPT could all be achieved in this system.

[0020] In one embodiment, the module PV.sub.n and its DC-PO could be replaced with a DC/DC converter that feeds power from the two terminals of the entire string to the line capacitor. In another embodiment, a power source other than PV module could be used to replace PV.sub.n in the input port of DC-PO.

[0021] In some embodiments, the hybrid PPP shown in FIG. 1 could be used to process the power in sub-modules within the same PV module. In other embodiment, more than one PV module could be connected in parallel or series across the same port of a DPP.

[0022] The converters DC-PO, DPP.sub.n1 and DPP.sub.n+1 could be non-isolated or isolated converters. Moreover, DPP.sub.n1 and DPP.sub.n+1 can be bidirectional, as well as unidirectional. The converters DC-PO, DPP.sub.n1 and DPP.sub.n+1 can be buck, boost, buck-boost, resonant converters, and variations of these topologies in isolated and non-isolated forms.

[0023] A generalized example of a PPP system is shown in FIG. 2. The string in FIG. 2 has a number N.sub.P of PV modules connected in series. The modules PV.sub.1, PV.sub.2, . . . PV.sub.n1 are connected in the lower part of the string below C.sub.lin, while the modules PV.sub.n+1, PV.sub.n+2, . . . PV.sub.Np are connected in the upper part above C.sub.lin. In this example, the number of PV modules connected below C.sub.lin is equal to the number of PV modules connected above it. However, in general, these two numbers could be different, and it is also possible to have one of the two numbers as zero.

[0024] The MPP of module PV.sub.x is tracked by driving the converter DPP.sub.x, x=1, 2, . . . n1, n+1, N.sub.p. DPP.sub.x measures the current/voltage of PV.sub.x and supplies/draws current from the PV module or C.sub.lin connected to its other port such that the MPP of the module PV.sub.x is tracked. The number of DPPs is equal to the number of modules, excluding the one that is driven by DC-PO. Therefore, local control for DPP.sub.x can be applied using only local measurements of voltages and currents in its two ports by a microcontroller in the DPP.sub.x circuit to track the MPP of PV.sub.x. It is clear that merely local control is needed for driving DPPs and DC-PO, which simplifies the system operation significantly and makes the system modular and easily scalable.

[0025] Two simulation studies were conducted to verify the effectiveness of the present method for PPP. In both studies, a string composed of five PV modules is considered. In the first simulation, the present system with buck-boost type DC-PO was tested, while in the second, a buck DC-PO was investigated, while the DPPs in both simulations are taken as buck-boost DC/DC converters. Bidirectional DPPs are used in the first simulation, and Table 1 shows the parameters of that simulation. From the table, it is clear that the PV modules have different MPP currents.

TABLE-US-00001 TABLE 1 Parameters of PPP Simulated System with Buck-Boost DC-PO I.sub.m,1 12.5 A I.sub.m,2 12.0 A I.sub.m,3 12.0 A I.sub.m,4 11.5 A I.sub.m,5 11.0 A DPP Inductor 600 H C.sub.lin 2 mF

[0026] The output currents of the five modules are shown in plot series 300 of FIGS. 3A through 3E. All PV modules maintained MPP operating throughout the system operation. Positive duty ratio represents supplying power from the PV module toward the direction of C.sub.lin while negative duty ratios represent the case of absorbing current for the direction of C.sub.lin. Since PV.sub.1 and PV.sub.2 have high MPP currents, they could achieve MPP operation by supplying extra currents toward the direction C.sub.lin, while PV.sub.4 and PV.sub.5 needed to consume current from the direction of C.sub.lin, and the values of their duty ratios, shown in plot series 400 of FIGS. 4A through 4E, reflect these facts. These drawings show clearly fast MPPT through a simple and modular control system.

[0027] In the second simulation, a buck-type DC-PO was used, while the DPPs were of unidirectional type. The parameters of the simulation are listed in Table 2. Since all DPPs need to absorb currents from the C.sub.lin direction in the buck DC-PO simulation, their duty ratios must always be negative.

TABLE-US-00002 TABLE 2 Parameters of PPP simulated system with buck DC-PO I.sub.m,1 12.5 A I.sub.m,2 11.0 A I.sub.m,3 12.5 A I.sub.m,4 11.5 A I.sub.m,5 11.0 A DPP Inductor 600 H C.sub.lin 2 mF

[0028] Plot series 500 of FIGS. 5A through 5E show the output currents of the PV modules where they match the required values of the MPP currents listed in Table 2. The duty ratios are always negative, and they are adjusted to track the MPP of the various PV modules, as shown in plot series 600 of FIGS. 6A through 6E.

[0029] It is to be understood that the present invention is not limited to the embodiments described above, but encompasses any and all embodiments within the scope of the following claims.