JP6155880B2 - Power supply - Google Patents

Description

  The present invention relates to a power supply device that includes a plurality of power converters in parallel, converts DC power selectively obtained from a DC power supply device or a battery device into power of a predetermined voltage, and outputs the power.

  Recently, an intelligent power supply (IPS) and an energy management system (EMS) have attracted attention as a power supply device using a solar power generation device that uses natural energy. FIG. 6 shows a schematic configuration of this type of power supply device, which includes a DC power supply (PV) 1 such as a solar power generation device and a battery device (BATT) 2 capable of storing DC power energy. Further, the power supply device charges the battery device 2 while converting the DC power obtained from the DC power supply device (PV) 1 into power of a predetermined voltage, and the DC power obtained from the battery device 2. A bidirectional power conversion device 4 that converts power into power of a predetermined voltage is provided. The power conversion device 4 for the battery device 2 basically stores the insufficient power amount in the battery device 2 when the DC power amount (power generation amount) generated by the DC power supply device 1 using natural energy is small. It plays a role of supplementing with the generated DC power.

  The power supply apparatus basically supplies DC power of a predetermined voltage obtained from the power converters 3 and 4 to the DC load 6 via the DC bus 5. In addition, the power supply device provides the battery device 2 via the power conversion device 4 with surplus power that exceeds the required power amount of the DC load 6 among the DC power obtained from the power conversion device 3. The battery device 2 is charged or configured to be output to the system power supply 8 via a power conditioner (PCS) 7.

  The power conditioner (PCS) 7 receives and supplies AC power to and from the system power supply 8. When the power supplied from the power supply device to the DC load 6 is insufficient, this power shortage It plays a role of supplementing the amount with electric power obtained from the system power supply 8. The power conversion device 4 also plays a role of charging the battery device 2 with power obtained from the power conditioner (PCS) 7 as necessary. The power supply apparatus configured as described above is as described in detail in, for example, Patent Document 1 and the like.

JP 2012-210018 A

  The power converters 3 and 4 are generally configured by providing a plurality of power converters 3a and 4a in parallel. Specifically, when the maximum power capacity (maximum power generation amount) of the DC power supply device 1 is 20 kW, for example, 10 power converters 3a and 4a each having 2 kW are provided in parallel, and each of the power conversion devices 3 and 4 is provided. Composed. Further, the power conditioner (PCS) 7 having a maximum power capacity of 20 kW is used in accordance with the maximum power capacity of the DC power supply device 1. In this case, the load power capacity of the DC load 6 is limited to 20 kW.

  Each of the power converters 3a and 4a is selectively controlled according to, for example, the required power amount of the DC load 6 and the DC power amount (output power capacity; power generation amount) that can be output by the DC power supply device 1. The Specifically, when the required power amount of the DC load 6 is 5 kW, for example, three power converters 3a are operated in parallel. Further, when the required power amount of the DC load 6 is 15 kW and the output power capacity of the DC power supply device 1 is 9 kW at this time, for example, five power converters 3a and three power converters 4a Are operated in parallel. When the required power amount of the DC load 6 is 20 kW at the maximum, the power converters 3a and 4a are set so that the total output power capacity of the power converter 3a and the power converter 4a is 20 kW. Are controlled.

  Therefore, it can be said that the conventional general power supply apparatus shown in FIG. 6 efficiently operates the plurality of power converters 3a and 4a constituting the two systems of the power converters 3 and 4, respectively. It is difficult and the redundancy of the power converter is large. Moreover, the plurality of power converters 4a constituting the power conversion device 4 are bidirectional, and are more expensive than the plurality of power converters 3a constituting the power conversion device 3. Therefore, it is desired to suppress the redundancy of the above-described power converter and to realize a power supply device such as the above-described intelligent power supply (IPS) and energy management system (EMS) at low cost.

  The present invention has been made in consideration of such circumstances, and an object thereof is to provide a power supply device having a simple and inexpensive configuration capable of minimizing the redundancy of a plurality of power converters provided in parallel. There is to do.

In order to achieve the above object, a power supply device according to the present invention includes a DC power supply device that generates DC power, such as a solar power generation device, a battery device that stores DC power, and the DC power supply device or the battery. A power conversion device that converts DC power obtained from the device into power of a predetermined voltage and outputs the power,
In particular, the power conversion device, a plurality of power converters provided in parallel, and an input switch that selectively supplies DC power obtained from the DC power supply device or the battery device to each of these power converters, An output switch that selectively outputs each power converted by a plurality of power converters to the battery device or an externally connected device; and a control device that controls the input switch and the output switch in association with each other. It is characterized by comprising.

  Preferably, when the power capacity required for the power conversion device is P [W], the plurality of power converters have a power capacity of P / n (where n is a natural number of 2 or more) [W], respectively. This is realized as (n + 1) power converters.

  Incidentally, the plurality of power converters include, for example, DC-DC converters that are selectively operated in synchronization with each other. The DC power obtained from each of these DC-DC converters receives AC power between the battery device or externally connected devices, specifically a DC load or a system power supply via the output switch. It is selectively supplied to the power conditioner to be electrified.

  Alternatively, the plurality of power converters are DC-AC converters that are operated in synchronization with each other, for example. The AC power obtained from each of these DC-AC converters is the AC-DC converter used for charging the battery device, or the externally connected device, specifically, an AC load or a system power supply. The power is selectively supplied to a power conditioner that receives and supplies AC power.

  Preferably, the DC power supply device comprises, for example, a solar power generation device or a wind power generation device or a tidal current power generation device provided with an AC-DC converter in an output stage. The control device is configured to switch and control the input switch and the output switch according to the amount of power supplied from the DC power supply device and the amount of power required by the externally connected device, for example, the amount of load power. .

  The input switch can select DC power obtained from the power conditioner that receives and supplies AC power to and from a system power supply instead of DC power obtained from the DC power supply device or the battery device. It is also preferable to configure as

  According to the power supply device having the above-described configuration, a plurality of power converters (DC-DC converters or DC-AC converters) provided in parallel by selectively switching and controlling the input switch and the output switch, respectively. ) Can be switched. Specifically, each of the plurality of power converters is used as a power converter for supplying power from the DC power supply device to a load, and a power converter for supplying power from the DC power supply device to the battery device Or alternatively, it can function as a power converter for supplying power from the battery device to the load.

  Accordingly, it is possible to selectively perform power supply to an external device such as a load and charging of the battery device by effectively utilizing a single power conversion device configured by providing a plurality of power converters in parallel. This makes it possible to reduce the redundancy required for the power converter. For example, when the power capacity required for the power converter is P [W], (n + 1) power converters each having a power capacity of P / n (where n is a natural number of 2 or more) [W] Just use them in parallel. Moreover, it is only necessary to use a unidirectional power converter.

  Each of the power converters can be effectively utilized only by selectively switching the roles of the plurality of power converters via the input switch and the output switch. Therefore, the power conversion device is constructed using the minimum number of power converters, and the power supply device can be realized easily and inexpensively.

The schematic block diagram of the electric power supply apparatus which concerns on one Embodiment of this invention. The figure which shows the basic connection relationship between the power converter, DC power supply device, battery apparatus, and DC load via an input switch and an output switch. The figure which shows the operation | use form of the power converter set selectively. The figure which shows an example of the electric power distribution with respect to the electric power supply apparatus shown in FIG. The schematic block diagram of the electric power supply apparatus which concerns on another embodiment of this invention. The schematic block diagram which shows an example of the conventional electric power supply apparatus.

  Hereinafter, a power supply apparatus according to an embodiment of the present invention will be described with reference to the drawings.

  The power supply device 10 is suitable for realizing the intelligent power source (IPS) and energy management system (EMS) constructed by utilizing a natural energy power generation device represented by a solar power generation device. Specifically, it is configured as shown in FIG. Here, the same parts as those of the conventional power supply apparatus shown in FIG. 6 are denoted by the same reference numerals, and repeated description thereof is omitted.

  This power supply device 10 is characterized by converting DC power obtained from the DC power supply device (PV) 1 such as a solar power generation device or the battery device (BATT) 2 into power of a predetermined voltage and outputting it. It is in the point provided only with one power converter device 11 which performs. This power converter 11 is configured by providing a plurality (m units) of power converters (for example, DC-DC converters) 12 (12a to 12m) in parallel. A plurality of input switches 13 (13a to 13m) and a plurality of output switches 14 (14a to 14m) are provided corresponding to the power converters 12 (12a to 12m), respectively.

  Incidentally, the input switch 13 (13a to 13m) selectively inputs the DC power obtained from the DC power supply device 1 or the power obtained from the battery device 2 to the power converter 12 (12a to 12m), respectively. Take a role. In addition, the output switch 14 (14a to 14m) outputs DC power of a predetermined voltage output from the power converter 12 (12a to 12m) to an externally connected device such as the DC load 6 or the battery device 2. It plays the role of selectively supplying to.

  The input switch 13 (13a to 13m) and the output switch 14 (14a to 14m) are relay switches that are selectively switched and controlled, or semiconductors such as IGBTs and MOS-FETs that are electronically controlled to be turned on and off. It consists of a switch. These input switches 13 (13a to 13m) and output switches 14 (14a to 14m) are selectively controlled in association with each other under the control of the control device 15.

  Specifically, the control device 15 depends on the output power capacity (power generation amount) of the DC power supply device 1, the supply power capacity (storage power capacity) of the battery device 2, the load capacity of the DC load 6, and the like. The input switch 13 (13a to 13m) and the output switch 14 (14a to 14m) are respectively controlled so as to efficiently operate the power converter 12 (12a to 12m). At the same time, the control device 15 also has a control function for selectively operating the plurality of power converters 12 (12a to 12m). The selective operation control of the plurality of power converters 12 (12a to 12m) is determined by the converted power capacity required for the power converter 11.

  Incidentally, when the maximum power capacity (maximum power generation amount) that can be output by the DC power supply device 1 is P [W], the maximum conversion power capacity required for the power conversion device 11 is determined as P [W]. The power conversion device 11 having a conversion power capacity of P [W] has, for example, m (= n + 1) power conversions each having a conversion power capacity of P / n (where n is a natural number of 2 or more) [W]. It implement | achieves by providing the container 12 (12a-12m) in parallel.

  Note that the supply power capacity (storage power capacity) of the battery device 2 can generally obtain a maximum P [W] output power over a predetermined time in accordance with the maximum power capacity of the DC power supply device 1. Is set as follows. The power capacity (load capacity) of the DC load 6 connected to the power supply apparatus 10 and supplied with power from the power supply apparatus 10 is normally limited within the range of the maximum power capacity of the DC power supply apparatus 1. The

  FIG. 2 shows a basic connection relationship with respect to the DC power supply device 1, the battery device 2 and the DC load 6 for explaining the role of the power converter 12 in the power supply device 10 configured as described above. ing. As shown in FIG. 2, the input terminal of the power converter 12 is connected to the DC power supply device 1 and the battery device 2 via the input switch 13. The power converter 12 performs a power conversion operation by inputting DC power from the DC power supply device 1 or DC power from the battery device 2 by selectively switching the input switch 13.

  The output terminal of the power converter 12 is connected to the DC load 6 and the battery device 2 via the output switch 14. Then, the DC power output from the power converter 12 is supplied to the DC load 6 by selective switching of the output switch 14 or is supplied to the battery device 2 to charge the battery device 2. It has become so.

Here, the control signals X and Y for switching and controlling the input switch 13 and the output switch 14 are respectively the output power capacity (power generation amount) of the DC power supply device 1 and the supply power capacity (storage power capacity) of the battery device 2. , And according to the load capacity of the DC load 6 and the like under the control device 15 as follows. However, in the following table, the values a and b of the control signals X and Y indicate the switch contacts on the side where the input switch 13 and the output switch 14 are selectively connected (see FIG. 2).

  Therefore, by giving (a, a) as the control signals X, Y and controlling the switching of the input switch 13 and the output switch 14, the power converter 12 is connected to the DC power source as shown in FIG. It is interposed between the device 1 and the DC load 6. In the first operation mode, the DC power output from the DC power supply device 1 is fed to the DC load 6 through the power converter 12. In this case, the battery device 2 is disconnected from the DC power supply path.

  Further, by giving (a, b) as the control signals X, Y and controlling the switching of the input switch 13 and the output switch 14, the power converter 12 is connected to the DC power source as shown in FIG. It is interposed between the device 1 and the battery device 2. In the second operation mode, the DC power output from the DC power supply device 1 is fed to the battery device 2 via the power converter 12 to charge the battery device 2. In this case, the DC load 6 is disconnected from the DC power supply path, and therefore the DC load 6 is not supplied with power.

  Further, (b, a) is given as the control signals X and Y to switch and control the input switch 13 and the output switch 14, whereby the power converter 12 is connected to the battery device as shown in FIG. 2 and the DC load 6. In the third operation mode, DC power output from the battery device 2 is supplied to the DC load 6 via the power converter 12. In this case, the DC power supply device 1 is disconnected from the DC power supply path.

  It is to be noted that giving (b, b) as the control signals X and Y is prohibited because the input and output of the power converter 12 are short-circuited. Therefore, the input switch 13 and the output switch 14 are selectively switched and controlled so as to set the first to third operation modes described above. Such switch control is executed alternatively for each of the plurality of power converters 12 (12a to 12m) described above. In particular, the switch control for the plurality of power converters 12 (12a to 12m) is executed in association with each other in accordance with, for example, the output power amount of the DC power supply device 1.

  FIG. 4 shows that when the output power capacity of the DC power supply device 1 is 20 kW and the load power amount of the DC load 6 at this time is 15.5 kW, a plurality (11 units) of the power converters 12 (12a) Shows an example of power distribution for ˜12 m). In this case, since the load power amount of the DC load 6 is 15.5 kW, as described above, the eight power converters 12 (12a to 12m) having a conversion power capacity of 2.0 kW (2.0 kW × 8). = 16 kW) is used to supply power to the DC load 6.

  Specifically, the input switch 13 (13a to 13m) is connected to the DC power supply device 1 side (contact a side), and eight of the output switches 14 (14a to 14m) are connected to the DC load 6 side ( By connecting to the contact a side), power is supplied to the DC load 6. In this case, among the eight power converters 12 (12a to 12m), the seven power converters 12 (12a to 12m) are respectively operated with a converted power amount of 2.0 kW. Then, the remaining one of the power converters 12 (12a to 12m) is operated with a converted power amount of 1.5 kW, so that a total of 15.5 kW of DC power is supplied to the DC load 6.

  On the other hand, of the 20 kW DC power output from the DC power supply device 1, as described above, 15.5 kW DC power is supplied to the DC load 6, so the surplus power amount of the DC power supply device 1 is 4. 5 kW (= 20 kW-15.5 kW). Accordingly, the remaining three of the output switches 14 (14a to 14m) are connected to the battery device 2 side (contact point b side) so as to charge the battery device 2 using this surplus power. Then, using the output DC power of the three power converters 12 (12a to 12m) connected to the battery device 2 via the output switch 14 (14a to 14m), the DC power is 4.5 kW. The battery device 2 is charged.

  Specifically, of the three power converters 12 (12a to 12m), two power converters 12 (12a to 12m) are operated with a converted power amount of 2.0 kW. Then, the remaining one power converter 12 (12a to 12m) is operated with a converted power amount of 0.5 kW, thereby supplying a total of 4.5 kW of DC power to the battery device 2. As a result, all of the DC power obtained from the DC power supply device 1 is effectively used to supply power to the DC load 6 and to charge the battery device 2 with the surplus power.

  Here, as described above, the power conversion device 11 has a conversion power capacity of P / n [W] with respect to the conversion power capacity of P [W] required for the power conversion device 11, respectively (= This is realized by providing n + 1) power converters 12 (12a to 12m) in parallel. That is, in addition to the number of power converters 12 (12a to 12m) satisfying the conversion power capacity required for the power conversion device 11, one more power converter 12 is added, for a total of 11 power converters. The power converter 11 is constructed by providing power converters 12 (12a to 12m) in parallel.

  This one added power converter 12 is for corresponding to the so-called fraction of the DC power supplied to the DC load 6 and the battery device 2 respectively. In addition, the fractional part is the maximum conversion of the predetermined number k of power converters 12 (12a to 12m) with respect to the conversion power capacity Pa [W] required for the plurality of power converters 12 (12a to 12m). The difference between the total converted power amount (Po × k) [W] and the required converted power capacity Pa [W] when operated with the power Po [W], and the maximum converted power Po [W]. The amount of electric power that is not satisfied (Pa−Po × k) [W]. Such fraction of DC power is dealt with by controlling the amount of converted power in one of the power converters 12 (12a to 12m).

  By the way, it is not possible to supply power to each of the DC load 6 and the battery device 2 from one power converter 12 at the same time, and power distribution cannot be performed. In order to deal with such a problem, one power converter 12 is additionally provided as described above. As described above, the two power converters 12 share the fraction of the power to be distributed and supplied to each of the DC load 6 and the battery device 2 from one power converter 12. Each is configured to perform power conversion. Therefore, according to the power supply apparatus 10 configured as described above, the DC power obtained from the DC power supply apparatus 1 is wasted by effectively utilizing the plurality of power converters 12 (12a to 12n) provided in parallel. It becomes possible to supply to each of the DC load 6 and the battery device 2 without having to.

  Thus, according to the power supply device 10 configured as described above, the DC power obtained from the DC power supply device 1 by effectively utilizing one system of the power conversion device 11 is used as the DC load 6 and the battery device 2. Can be supplied simultaneously. Further, by switching the input switch 13 (13a to 13m), the DC power obtained from the battery device 2 instead of the DC power supply device 1 can be supplied to the DC load 6.

  In addition, according to the power supply device 10 of the present invention, one system of the power conversion device as compared with the conventional power supply configured to include the two systems of the power conversion devices 3 and 4 shown in FIG. 11 can be provided, and the number of the plurality of power converters 12 (12a to 12m) constituting the power converter 11 can be significantly reduced. Furthermore, a unidirectional DC-DC converter can be used as these power converters 12 (12a to 12m), and there is no need to use a conventional expensive bi-directional DC-DC converter. Therefore, the effect that the said power converter device 11 and by extension, the electric power supply apparatus 10 can be constructed | assembled cheaply is exhibited.

  By the way, although embodiment mentioned above comprises the feed system of direct-current power, when constructing the feed system of alternating current power, the present invention can be applied similarly. FIG. 5 shows a schematic configuration of a power supply device 20 that constitutes an AC power supply system. In this case, a plurality (m units) of power is used as the power conversion device 21 that converts the DC power obtained from the DC power supply device (PV) 1 or the battery device (BATT) 2 into AC power of a predetermined voltage and outputs it. A converter (DC-AC converter) 22 (22a to 22m) may be provided in parallel.

  In FIG. 5, the plurality of input switches 13 (13a to 13m) and the plurality of output switches 14 (14a to 14m) provided corresponding to the respective power converters 22 (22a to 22m) are omitted. ing. Also, here, AC power obtained from the system power supply 8 is converted to DC power via a first rectifier (REC) 23 and supplied to the power converter 21 and is output from the power converter 21. The AC power is converted to DC power via a second rectifier (REC) 24 and supplied to the battery device 2. Needless to say, when this AC power supply system is constructed, an AC load 25 is connected to the AC power supply device 20 instead of the DC load 6.

  In the case of this embodiment, in addition to the DC power obtained from the DC power supply (PV) 1 and the battery device (BATT) 2 as the input switch 13 (13a to 13m), the first rectifier A three-input type that can alternatively select DC power obtained from (REC) 23 is used. Further, as the output switch 14 (14a to 14m), the AC load 25, the second rectifier (REC) 24, or a three-output type that can alternatively output AC power to the system power supply 8 is used. It is done.

  Also in the power supply device 20 configured in this manner, the DC power obtained from the DC power supply device (PV) 1 and the battery device (BATT) 2 is determined in a predetermined manner, similarly to the power supply device 10 according to the above-described embodiment. It can be converted into voltage AC power and supplied to the AC load 25. In addition, the battery device 2 can be charged using DC power obtained from the DC power supply (PV) 1 or DC power obtained from the first rectifier (REC) 23. Furthermore, AC power output from a plurality of power converters (DC-AC converters) 22 (22a to 22m) constituting the power converter 21 can be supplied to the system power supply 8.

  Moreover, the plurality of power converters (DC-AC converters) 22 (22a to 22m) can be simply and effectively simply by switching control of the input switch 13 (13a to 13m) and the output switch 14 (14a to 14m). ) Operation mode can be changed. Therefore, similar to the previous embodiment, the configuration can be simplified and the power supply device 20 can be constructed at low cost.

  In addition, this invention is not limited to each embodiment mentioned above. Here, a solar power generation device has been described as an example of the DC power supply device 1, but the present invention can be similarly applied to a case where a wind power generation device or a tidal current power generation device using natural energy is used. However, since these wind turbine generators and tidal current generators generally generate AC power, an AC-DC converter is provided in the output stage so that the AC power is converted into DC power and output. Configure it. The DC power supply device 1 preferably includes a DC voltage stabilizing circuit such as a PWM rectifier at its output stage.

  When the amount of DC power stored in the battery device 2 reaches its maximum value, the excess DC power obtained from the DC power supply device 1 is passed through the power conditioner (PCS) 7. Needless to say, the system power supply 8 may be fed. Furthermore, when the amount of DC power obtained from the DC power supply device 1 is reduced, it is needless to say that the insufficient power amount generated by this can be compensated by the power supplied from the battery device 2 or the system power supply 8. It is. Further, the number of the plurality of power converters 12 (12a to 12m) and 22 (22a to 22m) constituting the power converters 11 and 21 and the maximum amount of the converted power according to the specifications of the power supply apparatuses 10 and 20 Is sufficient. In addition, the present invention can be variously modified and implemented without departing from the scope of the invention.

1 DC power supply (PV)
2 Battery device (BATT)
3, 4 Power converter 3a, 4a Power converter (DC-DC converter)
6 DC load (DC-LOAD)
7 Power conditioner (PCS)
8 System power supply 10 Power supply device (DC power supply system)
11 power converter 12 (12a-12m) power converter (DC-DC converter)
13 (13a-13m) Input switch 14 (14a-14m) Output switch 15 Control device 20 Power supply device (AC power supply system)
21 power converter 22 (22a-22m) power converter (DC-AC converter)
23 First rectifier (REC)
24 Second rectifier (REC)
25 AC load

Claims (7)

A DC power supply device that generates DC power, a battery device that stores DC power, and a power converter that converts the DC power obtained from the DC power supply device or the battery device into power of a predetermined voltage and outputs the power. ,
The power conversion device includes a plurality of power converters provided in parallel, an input switch that selectively supplies each of these power converters with DC power obtained from the DC power supply device or the battery device, and the plurality of the power converters. An output switch that selectively outputs each power converted by the power converter to the battery device or an externally connected device, and a control device that controls the input switch and the output switch in association with each other. A power supply device comprising :
The plurality of power converters are DC-AC converters that are selectively operated in synchronization with each other,
The output switch selectively supplies AC power obtained from the DC-AC converter to an AC-DC converter for charging the battery device or the externally connected device. Feeding device .   The plurality of power converters each have a power capacity of P / n (where n is a natural number of 2 or more) [W] when the power capacity required for the power converter is P [W] ( The power supply apparatus according to claim 1, comprising n + 1) power converters. The power supply apparatus according to claim 1 , wherein the externally connected device is a power conditioner that receives and supplies AC power with an AC load or a system power supply.   The power supply device according to claim 1, wherein the DC power supply device is a solar power generation device.   The power supply device according to claim 1, wherein the DC power supply device is a wind power generator or a tidal current power generator that includes an AC-DC converter in an output stage.   2. The power supply according to claim 1, wherein the control device switches and controls the input switch and the output switch in accordance with a power supply amount of the DC power supply device and a required power amount of the externally connected device. apparatus.   The input switch is capable of selecting DC power obtained from a power conditioner that receives and supplies AC power to and from a system power supply instead of DC power obtained from the DC power supply device or the battery device. Item 2. The power supply device according to Item 1.