US20010035180A1 - Solar generation system - Google Patents
Solar generation system Download PDFInfo
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- US20010035180A1 US20010035180A1 US09/842,923 US84292301A US2001035180A1 US 20010035180 A1 US20010035180 A1 US 20010035180A1 US 84292301 A US84292301 A US 84292301A US 2001035180 A1 US2001035180 A1 US 2001035180A1
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- circuit
- solar cell
- boosting
- voltage
- generation system
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/34—Parallel operation in networks using both storage and other dc sources, e.g. providing buffering
- H02J7/35—Parallel operation in networks using both storage and other dc sources, e.g. providing buffering with light sensitive cells
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B10/00—Integration of renewable energy sources in buildings
- Y02B10/10—Photovoltaic [PV]
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B10/00—Integration of renewable energy sources in buildings
- Y02B10/20—Solar thermal
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S136/00—Batteries: thermoelectric and photoelectric
- Y10S136/291—Applications
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S136/00—Batteries: thermoelectric and photoelectric
- Y10S136/291—Applications
- Y10S136/293—Circuits
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S323/00—Electricity: power supply or regulation systems
- Y10S323/906—Solar cell systems
Definitions
- the present invention relates to a solar generation system. More specifically, the present invention relates to a solar generation system in which a DC power generated by an independent DC power source such as a solar cell is boosted by a booster unit and converted to an AC voltage by an inverter apparatus to supply power to general AC load for home and office use, or to feed power to existing utility power supply.
- an independent DC power source such as a solar cell
- an inverter apparatus to supply power to general AC load for home and office use, or to feed power to existing utility power supply.
- a solar cell as a DC power source outputs a DC power when there is high solar insolation.
- the DC power can be output solely by the solar cell without using other energy source such as a storage battery, and no poisonous substance is discharged. Therefore, the solar cell has been known as a simple and clean energy source.
- FIG. 15 is a block diagram showing an example of a conventional solar generation system. For simplicity of the drawing, only two solar cell strings 1 a and 1 b are shown in the solar generation system. It is needless to say that normally, a larger number of solar cell strings are provided. Generally, one standard solar cell string includes eight or nine solar cell modules (not shown) connected in series with each other.
- the solar cell strings are to be placed on the roof of a house, sometimes it is difficult to configure solar cell strings by arranging solar cell modules only that surface of the roof which faces southward and receiving the most of the sunshine. Solar cell modules that are positioned not on the southward surface of the roof may be arranged on the eastward or westward surface of the roof to form the solar cell strings. Sometimes, the solar cell strings are configured by placing small size solar cell modules arranged in the remaining peripheral regions after the solar cell modules are placed on the main portion of the southward surface of the roof. More specifically, sometimes the number of series-connected solar cell modules included in some solar cell strings is different from other solar cell strings. In such a case, different output voltages result from different solar cell strings.
- the abscissa represents output voltage V and the ordinate represents output power P.
- the curve S represents an output power from the standard solar cell string
- the curve N represents the output power from the substandard solar cell string.
- the standard solar cell string has the maximum output power Ps
- the substandard solar cell string has the maximum output power Pn.
- the output power that is the sum of these two output powers is as shown in FIG. 16B.
- the maximum output power Psn of the output power curve (S+N) shown in FIG. 16B is considerably smaller than the sum (Ps+Pn) of the maximum output powers Ps and Pn shown in FIG. 16A. The reason for this is that the voltage position for the maximum output power Ps of the standard solar cell string 1 a is different from the voltage position of the maximum output power Pn from the substandard solar cell string 1 b.
- a possible solution is to adjust output voltages from the plurality of solar cell strings.
- an impedance may be interposed between standard solar cell string 1 a and power conditioner 3 .
- This method is not practical, as the power is lost by the impedance.
- Another possibility is to use MG (Motor Generator) method to change the DC voltage. This method, however, is not preferable as mechanical vibration or noise is generated and the motor generator itself is bulky.
- boosted type DC-DC converters 80 a and 80 b having maximum power point tracking function are incorporated in each solar cell module or in each solar cell string, as shown in FIG. 17.
- Such a solar generation system is disadvantageous in that the circuit structure becomes complicated and in that voltage adjustment for the solar generation system as a whole must be performed in the initial design stage of each solar cell string having different output voltages.
- a main object of the present invention is to enable interconnection of a plurality of solar cell strings having different output voltages to a utility power supply in a simple manner, and to enable efficient use of the maximum output power of the solar cell strings.
- the present invention relates to a solar generation system in which a DC voltage output from a solar cell is boosted, and the boosted DC voltage is supplied to an inverter apparatus converting the DC voltage to an AC power, including a standard solar cell string having a standard number of solar cell modules connected in series, a substandard solar cell string having solar cell modules smaller in number than the standard number connected in series, a boosting circuit for boosting the DC voltage output from the substandard solar cell string to a DC voltage output from the standard solar cell string, and an input connecting circuit for supplying the DC voltage boosted by the boosting circuit and the DC voltage output from the standard solar cell string to the inverter apparatus.
- the boosting circuit boosts the DC voltage output from the substandard solar cell string at a boosting voltage ratio determined by the ratio between the standard number and the number smaller than the standard number.
- the system includes a switch for manually switching the boosting voltage ratio of the boosting circuit.
- the system includes a control circuit for controlling the boosting circuit by setting the boosting voltage ratio by pulse width modulation.
- a plurality of substandard solar cell strings are provided, and boosting circuits are provided for respective ones of the plurality of substandard solar cell strings, for boosting the DC voltage output from the corresponding one of the substandard solar cell strings.
- the boosting circuit is provided detachably between the substandard solar cell strings and the input connecting circuit.
- a power supply voltage is supplied to the boosting circuit from the substandard solar cell string.
- the input connecting circuit includes a backflow preventing circuit for preventing backflow of the current from the side of the boosting circuit to the substandard solar cell string, an input connecting/disconnecting circuit for connecting or disconnecting the substandard solar cell string and the boosting circuit, and a lightning surge preventing circuit for preventing entrance of lightning surge from the substandard solar cell string to the side of the boosting circuit.
- the system includes a voltage control circuit performing control to keep constant the boosting ratio, when the output voltage of the boosting circuit is lower than an upper limit set voltage.
- the voltage control circuit performs control to keep constant the upper limit voltage.
- the voltage control circuit changes the boosting ratio.
- the input connecting circuit includes a trip signal generating circuit generating a trip signal when the output voltage attains to an over voltage, and a breaker opening the connection between the substandard solar cell string and the input connecting circuit in response to the trip signal from the trip signal generating circuit.
- the trip signal generating circuit opens connection between the substandard solar cell string and the input connecting circuit by means of the breaker, by generating the trip signal, when there is a short-circuit in the boosting circuit.
- the trip signal generating circuit outputs a trip signal when it is detected that a short-circuit current flows in the boosting circuit and the temperature is increased.
- the trip signal generating circuit generates the trip signal when the output voltage of the boosting circuit exceeds a predetermined input voltage range.
- the boosting circuit includes a fuse for intercepting the short-circuit current from an output side.
- the fuse is connected in series with the boosting circuit, and opens the path of the short-circuit current, in accordance with the magnitude of the short-circuit current.
- the system includes a box placed outdoors, housing at least the input connecting circuit, and the box includes a drainage to guide rain water to a lower portion when rain water enters, and an outlet opening for discharging the rain water guided to the lower portion.
- a radiator is provided outside the box, for generation of heat from the boosting circuit and the backflow preventing circuit.
- the system includes a metal plate covering the radiator of the box and supporting the box on a wall surface.
- the box has a lid that can be opened/closed, and the input connecting circuit is operated with the lid opened.
- the system includes an indicator which is turned on when the boosting circuit is driven, and which is turned off in response to the stop of operation of the boosting circuit.
- FIG. 1 is a schematic block diagram representing the solar generation system in accordance with an embodiment of the present invention.
- FIGS. 2A and 2B are graphs representing output powers of a standard solar cell string and a substandard solar cell string and an output power provided when the output powers are connected in parallel.
- FIG. 3 is a block diagram showing a specific example of the booster unit included in the solar generation system shown in FIG. 1.
- FIG. 4 is a circuit diagram showing a specific example of the boosting circuit included in the booster unit.
- FIG. 5 shows a connection switch for manually determining the boosting voltage ratio in the booster unit.
- FIG. 6 is a block diagram representing a circuit for controlling the switching device in the boosting circuit.
- FIGS. 7A and 7B are graphs representing comparison between the triangular wave and the setting signal, and the gate pulse signal driving the switching device.
- FIG. 8 is a block diagram of the booster unit in accordance with one embodiment of the present invention.
- FIG. 9 is a block diagram of a control circuit in the booster unit shown in FIG. 1.
- FIGS. 10A to 10 C are waveform diagrams of various portions of the control circuit.
- FIGS. 11A to 11 F are waveform diagrams of various portions of the control circuit.
- FIGS. 12A to 12 C show the appearance of the box housing the booster unit in accordance with one embodiment of the present invention.
- FIGS. 13A and 13B show internal structure of the box shown in FIGS. 12A to 12 C.
- FIGS. 14A and 14B represent the structure of the lid of the box shown in FIGS. 12A to 12 C.
- FIG. 15 is a block diagram representing a conventional solar generation system.
- FIGS. 16A and 16B are graphs representing the output powers of the standard solar cell string and the substandard solar cell string shown in FIG. 15 and the output power when the output powers are connected in parallel.
- FIG. 17 is a block diagram illustrating a method of detecting an output voltage of a standard solar cell string and generating a boosting voltage ratio corresponding thereto in the booster unit.
- FIG. 1 is a block diagram of the solar generation system in accordance with an embodiment of the present invention.
- standard solar cell string 1 a includes eight or nine solar cell modules (not shown).
- the substandard solar cell string 1 b includes solar cell module smaller in number than the standard solar cell string 1 a.
- the output power of standard solar cell string 1 a is supplied to a DC/AC inverter 60 through a backflow preventing diode 50 a included in power conditioner 3 .
- the output power of substandard solar cell string 1 b is supplied to DC/AC inverter 60 through a booster unit 2 and a backflow preventing diode 50 b .
- power conditioner 3 output powers from the plurality of backflow preventing diodes 50 a are put together and supplied to DC/AC inverter 60 .
- the AC output power from DC/AC inverter is supplied to a utility power supply 4 through a protection circuit 70 .
- the output voltage of substandard solar cell string 1 b is made equal to the output voltage of standard solar cell string 1 a by booster unit 2 . Therefore, as can be seen from FIGS. 2A and 2B, the maximum output power that is the sum of the maximum output power of standard solar cell string 1 a and the output power from substandard solar cell string 1 b is supplied to utility power supply 4 .
- the abscissa represents an output voltage V and the ordinate represents the output power P.
- the curve S represents the output power from standard solar cell string 1 a
- the curve Nm represents the output power after the output power of substandard solar cell string 1 b is boosted by booster unit 2 .
- the voltage position of the maximum output Pn of substandard solar cell string 1 a boosted by booster unit 2 is the same as that voltage position of maximum output power Ps from the standard solar cell string. Therefore, when the output powers S and Nm are added, the output power curve will be S+Nm as shown in the graph of FIG. 2B, and thus, maximum output power (Ps+Pn) can be obtained.
- the solar generation system in accordance with one embodiment of the present invention, by a simple method of providing a booster unit 2 between the substandard solar cell string 1 b and power conditioner 3 , the maximum output power (Ps+Pn) that is the sum of the maximum output power Ps from the standard solar cell string 1 a and the maximum output power Pn from the substandard solar cell string 1 b can be supplied to the utility power supply. Further, the booster unit 2 is easily detachable, and therefore, when the substandard solar cell string 1 b is changed to a standard solar cell string 1 a , the unit can be detached.
- FIG. 3 is a schematic block diagram showing a specific example of booster unit 2 shown in FIG. 1.
- Booster unit 2 includes, in the order from an input terminal 21 at an input portion, an input EMI (Electro Magnetic Interference) filter 22 , a breaker 23 , a boosting circuit 24 , an output EMI filter 25 and an output terminal 26 .
- Output terminal 26 is connected to an input terminal of power conditioner 3 .
- EMI Electro Magnetic Interference
- the boosting ratio of boosting circuit 24 may be determined by the ratio of series-connected solar cell modules in the standard solar cell string 1 a and the substandard solar cell string 1 b .
- the circuit configuration of boosting circuit 24 in booster unit 2 is very simple. Further, a complicated control such as shown in FIG. 17, in which a DC/DC converter 80 b adjusts output voltage of substandard solar cell string 1 b using the output voltage of standard solar cell string 1 a as a reference voltage so that the output voltage of substandard solar cell string 1 b is made equal to the output voltage of standard solar cell string 1 a , is unnecessary.
- FIG. 4 is a circuit diagram showing a specific example of boosting circuit 24 included in booster unit 2 .
- boosting circuit 24 a reactor 101 and a diode 102 are connected in series, a capacitor 103 is connected between the cathode of diode 102 and the ground, and a switching device 104 is connected between the anode of diode 102 and the ground.
- switching device 104 a BJT (Bipolar Junction Transistor), an FET (Field Effect Transistor), an IGBT (Insulated Gate Bipolar Transistor) or a GTO (Gate Turn Off thyrister) may be used.
- BJT Bipolar Junction Transistor
- FET Field Effect Transistor
- IGBT Insulated Gate Bipolar Transistor
- GTO Gate Turn Off thyrister
- FIG. 5 schematically shows switches for determining the boosting ratio.
- the boosting ration can be determined by manually switching the switches. More specifically, solar cell modules of the same type having the same characteristics are generally used in the solar generation system. Therefore, the voltage ratio between the standard solar cell string 1 a and the substandard solar cell string 1 b, that is, the boosting ratio, can be determined by a simple fixed integer ratio such as 8:4 to 8:7 or 9:4 to 9:7.
- the boosting voltage ratio when the boosting voltage ratio is to be set, first, the number n 1 (8 or 9) of the solar cell modules included in standard solar cell string 1 a is set by a switch 27 a , and then, the number n 2 (4 to 7) of the solar cell modules included in the substandard solar cell string 1 b is set by a switch 27 b .
- the output voltage of booster unit 2 is set to n 1 /n 2 times the output voltage of substandard solar cell string 1 b connected thereto, and hence the output voltage becomes equal to the output voltage of standard serially connected solar cell string 1 a.
- FIG. 6 is a block diagram representing a control circuit used when boosting circuit 24 is driven by PWM (Pulse Width Modulation) control
- FIGS. 7A and 7B are waveform diagrams at various portions of FIG. 6.
- a signal set value is calculated in accordance with the following equation (1), by a signal setting operation unit 115 .
- the signal set value M resulting from the operation by signal setting operation unit 115 and a triangular wave T having an amplitude value of 0 to 1 oscillated by a triangular wave generating unit 116 are compared by a signal comparing unit 117 .
- signal comparing unit 117 When the signal set value M is smaller than the triangular wave T, signal comparing unit 117 outputs a gate ON level, and when the signal set value M is larger than the triangular wave T, the comparing unit outputs a gate OFF level.
- signal comparing unit 117 provides the pulse signal PS shown in FIG. 7B.
- the ratio between the period of pulse signal PS and the pulse width time (duty ratio) is represented by the following equation (2).
- the pulse signal PS is input to a gate drive unit 118 for boosting circuit 24 , and gate drive unit 118 drives switching device 104 shown in FIG. 4.
- gate drive unit 118 drives switching device 104 shown in FIG. 4.
- booster unit 2 In order to drive booster unit 2 , a power source therefor is necessary. When a battery that can provide output constantly such as a dry battery or a storage battery is used, booster unit will be in operation night and day, if there is no power switch provided. When the battery runs down, battery exchange is necessary. Further, in order to obtain power for booster unit 2 from utility power supply 4 , a separate interconnection becomes necessary. When the energy from the substandard solar cell string 1 b connected to booster unit 2 itself is used as the driving energy, booster unit will operate only in the day time when substandard solar cell string 1 b is in operation, and the operation is automatically stopped at night. Further, the solar cell never runs down, and therefore, unlike a dry battery or a storage battery that is drained, exchange is unnecessary. Further, interconnection from an external power source is unnecessary.
- FIG. 8 shows a solar generation system including the booster unit and the inverter apparatus in accordance with another embodiment of the present invention.
- standard solar cell string 1 a and substandard solar cell string 1 b are connected to booster unit, and respective output powers are input to booster unit 2 .
- Booster unit 2 is further connected to DC/AC inverter 60 , and DC/AC inverter 60 converts the DC power output from booster unit 2 to an AC power having the same phase and the frequency 50/60 Hz as the utility power supply 4 , and supplies it to the utility power supply 4 .
- Booster unit 2 includes a boosting apparatus 3 , a control circuit 15 , a trip signal generating unit 28 , backflow preventing diodes 6 a , 6 b , lightning surge absorbers 7 a , 7 b and input breakers 8 a and 8 b.
- Backflow preventing diodes 6 a and 6 b prevent backflow of the DC current from booster unit 2 to solar cell strings 1 a and 1 b .
- Lightning surge absorbers 7 a and 7 b prevent entrance of lightning surge from solar cell strings 1 a , 1 b to booster unit 2 .
- Input breakers 8 a and 8 b connect and disconnect solar cell string 1 a , 1 b , to and from booster unit 2 .
- Boosting apparatus 3 includes a reactor 9 , a switching device 10 , a diode 11 , a capacitor 13 , a fuse 12 and a temperature sensor 14 .
- Reactor 9 stores and discharges energy of the DC power input to booster unit 2 .
- Switching device 10 switches on/off, in accordance with a high frequency control output from control circuit 15 .
- Capacitor 13 stores the energy discharged from reactor 9 when switching device 10 turns off.
- Fuse 12 opens the circuit when a current higher than a set value flows.
- Temperature sensor 14 monitors the temperature of switching device 10 , and provides its output to trip signal generating unit 28 .
- trip signal generating unit 28 An output voltage Vout of booster unit 2 and a temperature signal Ts of temperature sensor 11 are applied to trip signal generating unit 28 , and when the output voltage Vout attains a voltage higher than a predetermined voltage, trip signal generating unit 28 outputs a trip signal Tp for tripping input breakers 8 a and 8 b.
- FIG. 9 is a specific block diagram of control circuit 15 shown in FIG. 8.
- control circuit 15 includes an initial boosting ratio setting unit 16 , an effective boosting ratio setting unit 17 , a boosting ratio comparing unit 18 , a signal setting operation unit 19 , a triangular wave generating unit 20 , a signal comparing unit 21 , a voltage comparing unit 22 , a signal setting operation unit 23 , a triangular wave generating unit 24 , a signal comparing unit 25 , an AND operating unit 26 and a gate drive unit 27 .
- FIGS. 10A to 10 C and 11 A to 11 F are waveform diagrams of the control circuit in the booster unit shown in FIG. 9.
- the signal set value Ma obtained by signal setting operation unit 19 and the triangular wave Ta having the amplitude value from 0 to 1 generated by triangular wave generating unit 20 are compared by the signal comparing unit 21 , and when the signal set value Ma is larger than the triangular wave Ta, signal comparing unit 21 performs PWM control, providing gate OFF level. As a result, signal comparing unit 21 provides a pulse signal PSa.
- a preset voltage Vref 1 and the output voltage Voutl of booster unit 2 are input at every sampling and compared by voltage comparing unit 22 . The result is output to signal setting operation unit 23 . Further, referring to FIG. 10, a signal set value Mb obtained at signal setting operation unit 23 and a triangular wave Tb having an amplitude value from 0 to 1 generated by triangular wave generating unit 24 are compared by signal comparing unit 25 , and when the signal set value Mb is larger than the triangular wave Tb, signal comparing unit 25 performs PWM control to output the gate OFF level.
- signal comparing unit 5 provides a pulse signal PSb.
- the pulse signals PSa and PSb are input to AND operating unit 26 , and an AND operation is performed.
- a pulse signal PSc is generated as shown in FIG. 10C.
- the pulse signal PSc is input to gate drive unit 27 for switching device 10 .
- booster unit 2 performs such a control that makes constant the boosting ratio. More specifically, control circuit 15 outputs the pulse signal PSa (FIG. 10A) providing the gate OFF level, based on the triangular wave Ta and the signal set value Ma obtained from initial boosting ratio ⁇ 1 and the effective boosting ratio ⁇ 2 , to AND operating unit 26 .
- voltage comparing unit 22 has the signal set value Mb having the amplitude value of 0 as an output of signal setting operation unit 23 input to signal comparing unit 25 . Then, PWM control based on the triangular wave Tb and signal set value Mb takes place in signal comparing unit 25 , and a pulse signal PSb having the pulse width of 1 such as shown in FIG. 11A is output to AND operating unit 26 .
- a pulse signal PSc which is similar to pulse signal PSa is output to gate drive unit 27 as a result of AND operation, as shown in FIG. 11B.
- the target of control is to make constant the boosting ratio.
- booster unit 2 When the DC/AC inverter 60 connected to the output side of booster unit 2 is not in operation, there is no load on booster unit 2 , and therefore, when booster unit 2 performs the boosting operation, the output voltage of booster unit 2 exceeds the tolerable input voltage range of DC/AC inverter 60 . Therefore, when the output voltage of booster unit 2 is higher than the tolerable input voltage range of DC/AC inverter 60 , booster unit 2 performs constant voltage control in which the boosting ratio ⁇ is varied to be smaller so that the output voltage of booster unit 2 is within the tolerable input voltage range of DC/AC inverter 60 .
- voltage comparing unit 22 has the signal setting operation unit 23 provide the signal set value Mb having the amplitude value not larger than 1 but larger than 0 (for example 0.1) to signal comparing unit 25 .
- Signal comparing unit 25 compares the triangular wave Tb with the signal set value Mb, performs PWM control, and the pulse signal PSb shown in FIG. 11D is output to AND operating unit 26 .
- a pulse signal PSb having such a pulse width as shown in FIG. 11D is input to the AND operating unit 26 , and when the pulse width of pulse signal PSb is smaller than the pulse signal PSa, AND operating unit 26 outputs a pulse signal PSc similar to the pulse signal PSb to gate drive unit 27 as shown in FIG. 11F.
- the control is switched from the control to keep boosting ratio constant to the control in which the boosting ratio ⁇ is made smaller, that is, to a constant voltage control by which the output voltage of booster unit 2 is set within the tolerable input voltage range of DC/AC inverter 60 .
- control target is to make constant the output voltage.
- trip signal generating unit 28 monitors the temperature Ts of switching device 10 through a temperature sensor 29 attached to switching device 10 . When a set temperature is reached, trip signal generating unit 28 transmits an input breaker trip signal Tp to trip input breaker 8 b , so that the path to the solar cell string 1 b is opened. In this manner, continuous flow of the short-circuit can be intercepted.
- Control circuit 15 may be implemented by an analog circuit or a digital circuit.
- FIGS. 12A to 12 C show appearance of the box containing the booster unit in accordance with one embodiment of the present invention.
- FIG. 12A is a front view
- 12 B is a side view
- 12 C is a bottom view.
- FIGS. 13A and 13 b show internal structure of the box shown in FIGS. 12A to 12 C.
- FIG. 13A is a front view with the cover of FIG. 12B removed
- FIG. 13B is a bottom view.
- FIGS. 14A and 14B show the structure of the lid member shown in FIG. 12A.
- FIG. 14A is a front view of the lid
- FIG. 14B is a cross section showing how the lid is attached.
- Box 30 shown in FIGS. 12A to 12 C accommodates booster unit 2 shown in FIG. 8 and, as shown in FIG. 12B, the box is placed vertically along a wall surface 40 outdoors.
- Box 30 includes a body portion 31 and a cover 32 covering the same.
- a barrier portion 33 serving as a drainage path is formed along the top and side surfaces in the body portion 31 .
- Barrier portion 33 guides rain water penetrating between body portion 31 and cover 32 to a lower portion of body portion 31 , and discharges the water to the outside through a rain outlet 34 as a discharge outlet, formed at the lower portion of body portion 31 .
- conductive portions of boosting apparatus 3 and control circuit 15 accommodated in the body 30 placed outdoors are protected from rain water.
- a heat sink 35 is attached on the lower portion (right side of FIG. 12B) of body portion 31 of box 30 .
- switching device 10 in boosting apparatus 3 and backflow preventing diodes 6 a and 6 b shown in FIG. 8 are attached, so that heat generated by the loss of switching device 10 in boosting apparatus 3 and by backflow preventing diodes 6 a and 6 b can be radiated to the outside, and thus radiation effect is improved.
- a metal plate 41 having a rectangular shape with one side opened is provided surrounding the heat sink 35 .
- a hook 42 is formed to hold the body portion 31 .
- box 30 can be attached in the vertical direction along the wall surface 40 .
- Metal plate 41 is formed to cover heat sink 35 , so as to prevent burning by accidentally touching the heat sink 35 which is heated by the heat generated by the loss from backflow preventing diodes 6 a and 6 b as well as switching device 10 when boosting apparatus 3 is in operation.
- indicator unit 36 At the central portion of cover 32 of box 30 .
- indicator unit 36 When boosting apparatus 3 is activated, indicator unit 36 is turned on, and when the operation of the apparatus stops, it turns off. Thus, whether booster unit 2 is in operation in the day time with much sunlight or not can be confirmed without the necessity to open the body of booster unit 2 . For example, if the indicator unit is off in the day time, it can be noticed that boosting apparatus 3 is not in operation. Therefore, whether booster unit 2 operates normally or not can be confirmed by the indicator unit 36 .
- a lid portion 37 is provided at a lower portion of cover 32 to cover an opening portion. When removed from body 31 , the lid portion 37 allows operation of input breakers 8 a and 8 b mounted on the body 31 , as shown in FIG. 13A.
- An attachment rail portion 38 is formed on one side of lid portion 37 as shown in FIG. 14A, and a fitting 39 is attached on the other side.
- a water proof member 45 such as rubber is adhered at the contact portion between lid portion 37 and body 31 .
- a space for installation dedicated for interconnection inside and outside of a building is saved as regards the connection between the DC power source such as solar cell strings 1 a and 1 b with the booster unit 2 and the DC/AC inverter 60 , the dedicated box 30 is integrated to reduce the cost of the overall apparatus, appearance inside and outside of the building is not spoiled as lines and wires for interconnection are reduced. Further, when booster unit 2 is in operation, overvoltage to DC/AC inverter 60 is prevented and generation of a short-circuit current in case of malfunction or short circuit of switching device 10 can be intercepted, thus a safe apparatus is realized.
- a boosting circuit boosting the DC power voltage, a backflow preventing circuit preventing backflow of current from the boosting means to the DC power source, an input connecting/disconnecting unit for connecting or disconnecting the DC power source to and from the boosting circuit, and a lightning surge preventing circuit preventing entrance of lightning surge from the DC power source to the boosting circuit are provided, so that backflow of current from the boosting apparatus and the inverter apparatus to the solar cell can be prevented and it is possible to safely connect or disconnect the solar cell and the boosting circuit and the boosting circuit and the inverter apparatus, at the time of engineering work, for example.
- boosting circuit performs the control to make constant the boosting ratio, so that a DC power comparable to that of a standard solar cell string can be supplied from a substandard solar cell string to the inverter apparatus. Therefore, a limited space of a building roof, for example, can be efficiently utilized.
- the boosting circuit performs control to make constant the upper limit voltage, and therefore overvoltage to the inverter apparatus possibly causing a malfunction can be prevented.
- trip signal generating circuit generates a trip signal when the output voltage becomes excessive, so that connection to the substandard solar cell string is opened by the opening circuit. While the booster unit is in operation in the day time with high amount of sunshine and control is performed to keep constant the boosting ratio or keep constant the voltage, the trip signal generating circuit trips and opens the circuit when an overvoltage is detected by the boosting circuit. Therefore, over voltage to the inverter apparatus possibly causing a malfunction can be prevented.
- the boosting circuit includes a fuse for intercepting the short-circuit current from the output side. Therefore, when the inverter apparatus is short-circuited, the short-circuit current flows from the inverter apparatus to the booster unit and the short-circuit current flows in the circuit, the fuse operates to open the circuit and prevents continuous flow of the short-circuit current. Therefore, malfunction of the booster unit caused by the short-circuit current can be prevented.
- the fuse is connected in series with the boosting circuit, and the path through which the short-circuit current flows is opened in accordance with the magnitude of the short-circuit current. Therefore, when the inverter apparatus is short-circuited and the short-circuit current flows from the inverter apparatus to the booster unit and the short-circuit current flows in the circuit, the fuse provided in the boosting circuit is blown off, opening the circuit. Thus, continuous flow of the short-circuit current can be prevented, and malfunction caused by the short-circuit current can be prevented.
- At least the input/output terminal is accommodated in a box placed outdoors, and the box includes a drainage path guiding the rain water to the lower portion when the rain water penetrates and a discharge outlet for discharging the rain water guided to the lower portion to the outside. Therefore, entrance of the rain water to the conductive portions of the inverter apparatus and the control circuit can be prevented. Further, as a dedicated box is formed integrally, the cost of the overall apparatus can be reduced.
- a radiator for generation of heat from the boosting circuit and the backflow preventing circuit to the outside is provided on the outside of the box.
- the effect of radiation can be enhanced.
- a lid portion that can be opened is provided on the box, and by operating the input connecting/disconnecting unit with the lid opened, it is possible to separate the booster unit from the DC power source in case of emergency.
- an indicator means that turns off when the boosting circuit is driven and turns off when the operation of the boosting circuit stops is provided on the box. Therefore, it can be readily confirmed whether the boosting circuit is normally operating or not.
Abstract
Description
- 1. Field of the Invention
- The present invention relates to a solar generation system. More specifically, the present invention relates to a solar generation system in which a DC power generated by an independent DC power source such as a solar cell is boosted by a booster unit and converted to an AC voltage by an inverter apparatus to supply power to general AC load for home and office use, or to feed power to existing utility power supply.
- 2. Description of the Background Art.
- A solar cell as a DC power source outputs a DC power when there is high solar insolation. The DC power can be output solely by the solar cell without using other energy source such as a storage battery, and no poisonous substance is discharged. Therefore, the solar cell has been known as a simple and clean energy source.
- FIG. 15 is a block diagram showing an example of a conventional solar generation system. For simplicity of the drawing, only two
solar cell strings - In the solar generation system, when the DC output power from
solar cell strings utility power supply 4, it is necessary to interpose apower conditioner 3 between thesolar cell strings utility power supply 4. When a plurality ofsolar cell strings 1 are to be interconnected to theutility power supply 4, the plurality ofsolar cell strings 1 are connected in parallel with thepower conditioner 3.Power conditioner 3 includesbackflow preventing diodes solar cell strings 1 connected in parallel. The DC power that has passed throughbackflow preventing diodes AC inverter 60, and supplied through aprotection circuit 70 to theutility power supply 4. - Conventionally, it is a common practice for the solar generation system in Japan that a plurality of solar cell strings included therein are placed on a main portion of a roof facing southward, and lines from the solar cell strings are connected to
power conditioner 3. - When the solar cell strings are to be placed on the roof of a house, sometimes it is difficult to configure solar cell strings by arranging solar cell modules only that surface of the roof which faces southward and receiving the most of the sunshine. Solar cell modules that are positioned not on the southward surface of the roof may be arranged on the eastward or westward surface of the roof to form the solar cell strings. Sometimes, the solar cell strings are configured by placing small size solar cell modules arranged in the remaining peripheral regions after the solar cell modules are placed on the main portion of the southward surface of the roof. More specifically, sometimes the number of series-connected solar cell modules included in some solar cell strings is different from other solar cell strings. In such a case, different output voltages result from different solar cell strings.
- For example, when a standard solar cell string including the standard number of series-connected solar cell modules and a substandard solar cell string including series-connected modules of smaller than the standard number are connected in parallel to the
power conditioner 3, only the power from the standard solar cell having the standard output voltage is input topower conditioner 3, and the power from the substandard solar cell string having the substandard output voltage lower than the standard output voltage cannot be fed to thepower conditioner 3. Even when the power from the substandard solar cell string is adapted to be fed topower conditioner 3, it is impossible to obtain the maximum output power that is the sum of the maximum power from the standard solar cell string and the maximum power from the substandard solar cell string, as can be seen from FIGS. 16A and 16B. - Unless the power from such a substandard solar cell string can be fed efficiently to
power conditioner 3, the area occupied by the substandard solar cell string would be wasted. - In the graphs of FIGS. 16A and 16B, the abscissa represents output voltage V and the ordinate represents output power P. In the graph of FIG. 16A, the curve S represents an output power from the standard solar cell string, while the curve N represents the output power from the substandard solar cell string. More specifically, the standard solar cell string has the maximum output power Ps, while the substandard solar cell string has the maximum output power Pn. The output power that is the sum of these two output powers is as shown in FIG. 16B. The maximum output power Psn of the output power curve (S+N) shown in FIG. 16B is considerably smaller than the sum (Ps+Pn) of the maximum output powers Ps and Pn shown in FIG. 16A. The reason for this is that the voltage position for the maximum output power Ps of the standard
solar cell string 1 a is different from the voltage position of the maximum output power Pn from the substandardsolar cell string 1 b. - In view of the foregoing, a possible solution is to adjust output voltages from the plurality of solar cell strings. For this purpose, an impedance may be interposed between standard
solar cell string 1 a andpower conditioner 3. This method, however, is not practical, as the power is lost by the impedance. Another possibility is to use MG (Motor Generator) method to change the DC voltage. This method, however, is not preferable as mechanical vibration or noise is generated and the motor generator itself is bulky. - In the solar cell generation system disclosed in Japanese Patent Laying-Open No. 8-46231, boosted type DC-
DC converters 80 a and 80 b having maximum power point tracking function are incorporated in each solar cell module or in each solar cell string, as shown in FIG. 17. Such a solar generation system is disadvantageous in that the circuit structure becomes complicated and in that voltage adjustment for the solar generation system as a whole must be performed in the initial design stage of each solar cell string having different output voltages. - In Japanese Patent Laying-Open No. 8-46231, an isolation transformer is connected. This increases the weight of the system and lowers power conversion efficiency. In case of a malfunction of the boosting circuit caused by a surge, it will trouble a repair person to climb on the roof and to exchange the solar cell module.
- Therefore, a main object of the present invention is to enable interconnection of a plurality of solar cell strings having different output voltages to a utility power supply in a simple manner, and to enable efficient use of the maximum output power of the solar cell strings.
- Briefly stated, the present invention relates to a solar generation system in which a DC voltage output from a solar cell is boosted, and the boosted DC voltage is supplied to an inverter apparatus converting the DC voltage to an AC power, including a standard solar cell string having a standard number of solar cell modules connected in series, a substandard solar cell string having solar cell modules smaller in number than the standard number connected in series, a boosting circuit for boosting the DC voltage output from the substandard solar cell string to a DC voltage output from the standard solar cell string, and an input connecting circuit for supplying the DC voltage boosted by the boosting circuit and the DC voltage output from the standard solar cell string to the inverter apparatus.
- Therefore, according to the present invention, as the DC voltage from the substandard solar cell string is increased to the DC voltage of the standard solar cell string, interconnection to the utility power supply is possible in a simple manner, and the sum of the maximum outputs from respective solar cell strings can be used as the final maximum output power.
- More preferably, the boosting circuit boosts the DC voltage output from the substandard solar cell string at a boosting voltage ratio determined by the ratio between the standard number and the number smaller than the standard number.
- More preferably, the system includes a switch for manually switching the boosting voltage ratio of the boosting circuit.
- More preferably, the system includes a control circuit for controlling the boosting circuit by setting the boosting voltage ratio by pulse width modulation.
- More preferably, a plurality of substandard solar cell strings are provided, and boosting circuits are provided for respective ones of the plurality of substandard solar cell strings, for boosting the DC voltage output from the corresponding one of the substandard solar cell strings.
- More preferably, the boosting circuit is provided detachably between the substandard solar cell strings and the input connecting circuit.
- More preferably, a power supply voltage is supplied to the boosting circuit from the substandard solar cell string.
- More preferably, the input connecting circuit includes a backflow preventing circuit for preventing backflow of the current from the side of the boosting circuit to the substandard solar cell string, an input connecting/disconnecting circuit for connecting or disconnecting the substandard solar cell string and the boosting circuit, and a lightning surge preventing circuit for preventing entrance of lightning surge from the substandard solar cell string to the side of the boosting circuit.
- More preferably, the system includes a voltage control circuit performing control to keep constant the boosting ratio, when the output voltage of the boosting circuit is lower than an upper limit set voltage.
- More preferably, when the output voltage of the boosting circuit is higher than the upper limit set voltage, the voltage control circuit performs control to keep constant the upper limit voltage.
- More preferably, the voltage control circuit changes the boosting ratio.
- More preferably, the input connecting circuit includes a trip signal generating circuit generating a trip signal when the output voltage attains to an over voltage, and a breaker opening the connection between the substandard solar cell string and the input connecting circuit in response to the trip signal from the trip signal generating circuit.
- More preferably, the trip signal generating circuit opens connection between the substandard solar cell string and the input connecting circuit by means of the breaker, by generating the trip signal, when there is a short-circuit in the boosting circuit.
- More preferably, the trip signal generating circuit outputs a trip signal when it is detected that a short-circuit current flows in the boosting circuit and the temperature is increased.
- More preferably, the trip signal generating circuit generates the trip signal when the output voltage of the boosting circuit exceeds a predetermined input voltage range.
- More preferably, the boosting circuit includes a fuse for intercepting the short-circuit current from an output side.
- More preferably, the fuse is connected in series with the boosting circuit, and opens the path of the short-circuit current, in accordance with the magnitude of the short-circuit current.
- More preferably, the system includes a box placed outdoors, housing at least the input connecting circuit, and the box includes a drainage to guide rain water to a lower portion when rain water enters, and an outlet opening for discharging the rain water guided to the lower portion.
- More preferably, a radiator is provided outside the box, for generation of heat from the boosting circuit and the backflow preventing circuit.
- More preferably, the system includes a metal plate covering the radiator of the box and supporting the box on a wall surface.
- More preferably, the box has a lid that can be opened/closed, and the input connecting circuit is operated with the lid opened.
- More preferably, the system includes an indicator which is turned on when the boosting circuit is driven, and which is turned off in response to the stop of operation of the boosting circuit.
- The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
- FIG. 1 is a schematic block diagram representing the solar generation system in accordance with an embodiment of the present invention.
- FIGS. 2A and 2B are graphs representing output powers of a standard solar cell string and a substandard solar cell string and an output power provided when the output powers are connected in parallel.
- FIG. 3 is a block diagram showing a specific example of the booster unit included in the solar generation system shown in FIG. 1.
- FIG. 4 is a circuit diagram showing a specific example of the boosting circuit included in the booster unit.
- FIG. 5 shows a connection switch for manually determining the boosting voltage ratio in the booster unit.
- FIG. 6 is a block diagram representing a circuit for controlling the switching device in the boosting circuit.
- FIGS. 7A and 7B are graphs representing comparison between the triangular wave and the setting signal, and the gate pulse signal driving the switching device.
- FIG. 8 is a block diagram of the booster unit in accordance with one embodiment of the present invention.
- FIG. 9 is a block diagram of a control circuit in the booster unit shown in FIG. 1.
- FIGS. 10A to10C are waveform diagrams of various portions of the control circuit.
- FIGS. 11A to11F are waveform diagrams of various portions of the control circuit.
- FIGS. 12A to12C show the appearance of the box housing the booster unit in accordance with one embodiment of the present invention.
- FIGS. 13A and 13B show internal structure of the box shown in FIGS. 12A to12C.
- FIGS. 14A and 14B represent the structure of the lid of the box shown in FIGS. 12A to12C.
- FIG. 15 is a block diagram representing a conventional solar generation system.
- FIGS. 16A and 16B are graphs representing the output powers of the standard solar cell string and the substandard solar cell string shown in FIG. 15 and the output power when the output powers are connected in parallel.
- FIG. 17 is a block diagram illustrating a method of detecting an output voltage of a standard solar cell string and generating a boosting voltage ratio corresponding thereto in the booster unit.
- FIG. 1 is a block diagram of the solar generation system in accordance with an embodiment of the present invention. In the solar generation system, for simplicity of the drawing, only one standard
solar cell string 1 a and one substandardsolar cell string 1 b are shown. It is needless to say that there may be larger number of solar cell strings. Generally, standardsolar cell string 1 a includes eight or nine solar cell modules (not shown). The substandardsolar cell string 1 b includes solar cell module smaller in number than the standardsolar cell string 1 a. - The output power of standard
solar cell string 1 a is supplied to a DC/AC inverter 60 through abackflow preventing diode 50 a included inpower conditioner 3. The output power of substandardsolar cell string 1 b is supplied to DC/AC inverter 60 through abooster unit 2 and abackflow preventing diode 50 b. Inpower conditioner 3, output powers from the plurality ofbackflow preventing diodes 50 a are put together and supplied to DC/AC inverter 60. The AC output power from DC/AC inverter is supplied to autility power supply 4 through aprotection circuit 70. - In the solar generation system such as shown in FIG. 1, the output voltage of substandard
solar cell string 1 b is made equal to the output voltage of standardsolar cell string 1 a bybooster unit 2. Therefore, as can be seen from FIGS. 2A and 2B, the maximum output power that is the sum of the maximum output power of standardsolar cell string 1 a and the output power from substandardsolar cell string 1 b is supplied toutility power supply 4. - Referring to FIGS. 2A and 2B, the abscissa represents an output voltage V and the ordinate represents the output power P. The curve S represents the output power from standard
solar cell string 1 a, and the curve Nm represents the output power after the output power of substandardsolar cell string 1 b is boosted bybooster unit 2. As can be seen from the graph of FIG. 2B, the voltage position of the maximum output Pn of substandardsolar cell string 1 a boosted bybooster unit 2 is the same as that voltage position of maximum output power Ps from the standard solar cell string. Therefore, when the output powers S and Nm are added, the output power curve will be S+Nm as shown in the graph of FIG. 2B, and thus, maximum output power (Ps+Pn) can be obtained. - In this manner, by the solar generation system in accordance with one embodiment of the present invention, by a simple method of providing a
booster unit 2 between the substandardsolar cell string 1 b andpower conditioner 3, the maximum output power (Ps+Pn) that is the sum of the maximum output power Ps from the standardsolar cell string 1 a and the maximum output power Pn from the substandardsolar cell string 1 b can be supplied to the utility power supply. Further, thebooster unit 2 is easily detachable, and therefore, when the substandardsolar cell string 1 b is changed to a standardsolar cell string 1 a, the unit can be detached. - FIG. 3 is a schematic block diagram showing a specific example of
booster unit 2 shown in FIG. 1.Booster unit 2 includes, in the order from aninput terminal 21 at an input portion, an input EMI (Electro Magnetic Interference)filter 22, abreaker 23, a boostingcircuit 24, anoutput EMI filter 25 and anoutput terminal 26.Output terminal 26 is connected to an input terminal ofpower conditioner 3. - The boosting ratio of boosting
circuit 24 may be determined by the ratio of series-connected solar cell modules in the standardsolar cell string 1 a and the substandardsolar cell string 1 b. Thus, the circuit configuration of boostingcircuit 24 inbooster unit 2 is very simple. Further, a complicated control such as shown in FIG. 17, in which a DC/DC converter 80 b adjusts output voltage of substandardsolar cell string 1 b using the output voltage of standardsolar cell string 1 a as a reference voltage so that the output voltage of substandardsolar cell string 1 b is made equal to the output voltage of standardsolar cell string 1 a, is unnecessary. - FIG. 4 is a circuit diagram showing a specific example of boosting
circuit 24 included inbooster unit 2. In boostingcircuit 24, areactor 101 and adiode 102 are connected in series, acapacitor 103 is connected between the cathode ofdiode 102 and the ground, and aswitching device 104 is connected between the anode ofdiode 102 and the ground. As switchingdevice 104, a BJT (Bipolar Junction Transistor), an FET (Field Effect Transistor), an IGBT (Insulated Gate Bipolar Transistor) or a GTO (Gate Turn Off thyrister) may be used. - When switching
device 104 is on, in the boostingcircuit 24, energy is stored in the reactor as current flows toreactor 101. When theswitching device 104 is turned off, the energy stored inreactor 101 is changed to a current, which chargescapacitor 103 throughdiode 102. When switchingdevice 104 is again turned on, energy is stored inreactor 101, and when switchingdevice 104 is turned off, the energy ofreactor 101 is changed to a current, and a voltage derived from the current is superposed on the voltage charged to thecapacitor 103, whereby the boosting is attained. - FIG. 5 schematically shows switches for determining the boosting ratio. In this example, the boosting ration can be determined by manually switching the switches. More specifically, solar cell modules of the same type having the same characteristics are generally used in the solar generation system. Therefore, the voltage ratio between the standard
solar cell string 1 a and the substandardsolar cell string 1 b, that is, the boosting ratio, can be determined by a simple fixed integer ratio such as 8:4 to 8:7 or 9:4 to 9:7. - Therefore, when the boosting voltage ratio is to be set, first, the number n1 (8 or 9) of the solar cell modules included in standard
solar cell string 1 a is set by aswitch 27 a, and then, the number n2 (4 to 7) of the solar cell modules included in the substandardsolar cell string 1 b is set by aswitch 27 b. By manually operating these twoswitches booster unit 2 is set to n1/n2 times the output voltage of substandardsolar cell string 1 b connected thereto, and hence the output voltage becomes equal to the output voltage of standard serially connectedsolar cell string 1 a. - FIG. 6 is a block diagram representing a control circuit used when boosting
circuit 24 is driven by PWM (Pulse Width Modulation) control, and FIGS. 7A and 7B are waveform diagrams at various portions of FIG. 6. - For the boosting voltage ratio set by the boosting
ratio setting unit 114 includingswitches setting operation unit 115. - (Signal Setting Value)=(set value of
switch 27 b)/(set value ofswitch 27 a) (1) - Referring to FIG. 7A, the signal set value M resulting from the operation by signal setting
operation unit 115 and a triangular wave T having an amplitude value of 0 to 1 oscillated by a triangularwave generating unit 116 are compared by asignal comparing unit 117. When the signal set value M is smaller than the triangular wave T,signal comparing unit 117 outputs a gate ON level, and when the signal set value M is larger than the triangular wave T, the comparing unit outputs a gate OFF level. As a result,signal comparing unit 117 provides the pulse signal PS shown in FIG. 7B. The ratio between the period of pulse signal PS and the pulse width time (duty ratio) is represented by the following equation (2). - (Duty Ratio)=1−(signal set value) (2)
- The pulse signal PS is input to a
gate drive unit 118 for boostingcircuit 24, andgate drive unit 118drives switching device 104 shown in FIG. 4. By utilizing such a method of boosting under PWM control, the boostingcircuit 24 can be realized in a simple structure. - In order to drive
booster unit 2, a power source therefor is necessary. When a battery that can provide output constantly such as a dry battery or a storage battery is used, booster unit will be in operation night and day, if there is no power switch provided. When the battery runs down, battery exchange is necessary. Further, in order to obtain power forbooster unit 2 fromutility power supply 4, a separate interconnection becomes necessary. When the energy from the substandardsolar cell string 1 b connected tobooster unit 2 itself is used as the driving energy, booster unit will operate only in the day time when substandardsolar cell string 1 b is in operation, and the operation is automatically stopped at night. Further, the solar cell never runs down, and therefore, unlike a dry battery or a storage battery that is drained, exchange is unnecessary. Further, interconnection from an external power source is unnecessary. - As described above, according to the embodiment, in a solar generation system including standard
solar cell string 1 a as well as substandardsolar cell string 1 b, interconnection to the utility power supply can be established in a simple manner, and a sum of the maximum outputs from respective solar cell strings can eventually be utilized as the maximum output power. - FIG. 8 shows a solar generation system including the booster unit and the inverter apparatus in accordance with another embodiment of the present invention.
- Referring to FIG. 8, standard
solar cell string 1 a and substandardsolar cell string 1 b are connected to booster unit, and respective output powers are input tobooster unit 2.Booster unit 2 is further connected to DC/AC inverter 60, and DC/AC inverter 60 converts the DC power output frombooster unit 2 to an AC power having the same phase and the frequency 50/60 Hz as theutility power supply 4, and supplies it to theutility power supply 4. -
Booster unit 2 includes a boostingapparatus 3, acontrol circuit 15, a tripsignal generating unit 28,backflow preventing diodes lightning surge absorbers input breakers -
Backflow preventing diodes booster unit 2 tosolar cell strings Lightning surge absorbers solar cell strings booster unit 2.Input breakers solar cell string booster unit 2. - Boosting
apparatus 3 includes areactor 9, aswitching device 10, adiode 11, acapacitor 13, afuse 12 and atemperature sensor 14.Reactor 9 stores and discharges energy of the DC power input tobooster unit 2.Switching device 10 switches on/off, in accordance with a high frequency control output fromcontrol circuit 15.Capacitor 13 stores the energy discharged fromreactor 9 when switchingdevice 10 turns off.Fuse 12 opens the circuit when a current higher than a set value flows.Temperature sensor 14 monitors the temperature of switchingdevice 10, and provides its output to tripsignal generating unit 28. An output voltage Vout ofbooster unit 2 and a temperature signal Ts oftemperature sensor 11 are applied to tripsignal generating unit 28, and when the output voltage Vout attains a voltage higher than a predetermined voltage, tripsignal generating unit 28 outputs a trip signal Tp for trippinginput breakers - FIG. 9 is a specific block diagram of
control circuit 15 shown in FIG. 8. Referring to FIG. 9,control circuit 15 includes an initial boostingratio setting unit 16, an effective boostingratio setting unit 17, a boostingratio comparing unit 18, a signalsetting operation unit 19, a triangularwave generating unit 20, asignal comparing unit 21, avoltage comparing unit 22, a signalsetting operation unit 23, a triangularwave generating unit 24, asignal comparing unit 25, an ANDoperating unit 26 and agate drive unit 27. - Initial boosting
ratio setting unit 16 sets the ratio between the number n1 of the solar cell modules included in standardsolar cell string 1 a and the number n2 of the solar cell modules included in substandardsolar cell string 1 b, that is, boosting ratio α1 (=n1/n2). Effective boostingratio setting unit 17 sets for every sampling, the effective boosting ratio α2 (=Vout1/Vin), from the input voltage Vin to thebooster unit 2 and the output voltage Vout1. - Initial boosting ratio α1 obtained from initial boosting
ratio setting unit 16 and the effective boosting ratio α2 obtained from effective boostingratio setting unit 17 are compared by boostingratio comparing unit 18, an error therebetween is amplified and output to signal settingoperation unit 19. - FIGS. 10A to10C and 11A to 11F are waveform diagrams of the control circuit in the booster unit shown in FIG. 9. Referring to FIG. 10A, the signal set value Ma obtained by signal setting
operation unit 19 and the triangular wave Ta having the amplitude value from 0 to 1 generated by triangularwave generating unit 20 are compared by thesignal comparing unit 21, and when the signal set value Ma is larger than the triangular wave Ta,signal comparing unit 21 performs PWM control, providing gate OFF level. As a result,signal comparing unit 21 provides a pulse signal PSa. - Further, a preset voltage Vref1 and the output voltage Voutl of
booster unit 2 are input at every sampling and compared byvoltage comparing unit 22. The result is output to signal settingoperation unit 23. Further, referring to FIG. 10, a signal set value Mb obtained at signalsetting operation unit 23 and a triangular wave Tb having an amplitude value from 0 to 1 generated by triangularwave generating unit 24 are compared bysignal comparing unit 25, and when the signal set value Mb is larger than the triangular wave Tb,signal comparing unit 25 performs PWM control to output the gate OFF level. - As a result,
signal comparing unit 5 provides a pulse signal PSb. The pulse signals PSa and PSb are input to AND operatingunit 26, and an AND operation is performed. As a result, a pulse signal PSc is generated as shown in FIG. 10C. The pulse signal PSc is input togate drive unit 27 for switchingdevice 10. - The operation of
booster unit 2 structured as above is as follow. As already described,booster unit 2 boosts the input voltage based on the boosting ratio α(=n1/n2) determined from the number n1 of the solar cell module in the standardsolar cell string 1 a and the number n2 of solar cell modules in substandardsolar cell string 1 b, and an output voltage therefrom is supplied to DC/AC inverter 60. When the output voltage ofbooster unit 2 is within the tolerable input voltage range of DC/AC inverter 60,booster unit 2 performs such a control that makes constant the boosting ratio. More specifically,control circuit 15 outputs the pulse signal PSa (FIG. 10A) providing the gate OFF level, based on the triangular wave Ta and the signal set value Ma obtained from initial boosting ratio α1 and the effective boosting ratio α2, to AND operatingunit 26. - At this time, as the output voltage Voutl of
booster unit 2 is within the input voltage range Vref1 of DC/AC inverter 60 (Vout1<Vref1),voltage comparing unit 22 has the signal set value Mb having the amplitude value of 0 as an output of signal settingoperation unit 23 input to signal comparingunit 25. Then, PWM control based on the triangular wave Tb and signal set value Mb takes place insignal comparing unit 25, and a pulse signal PSb having the pulse width of 1 such as shown in FIG. 11A is output to AND operatingunit 26. As the pulse signal PSb has thepulse width 1, a pulse signal PSc which is similar to pulse signal PSa is output togate drive unit 27 as a result of AND operation, as shown in FIG. 11B. At this time, the target of control is to make constant the boosting ratio. - When the DC/
AC inverter 60 connected to the output side ofbooster unit 2 is not in operation, there is no load onbooster unit 2, and therefore, whenbooster unit 2 performs the boosting operation, the output voltage ofbooster unit 2 exceeds the tolerable input voltage range of DC/AC inverter 60. Therefore, when the output voltage ofbooster unit 2 is higher than the tolerable input voltage range of DC/AC inverter 60,booster unit 2 performs constant voltage control in which the boosting ratio α is varied to be smaller so that the output voltage ofbooster unit 2 is within the tolerable input voltage range of DC/AC inverter 60. - More specifically, as the output voltage Voutl of
booster unit 2 is higher than the input voltage range Vref1 of DC/AC inverter 60 (Vout 1>Vref1), in thecontrol circuit 15,voltage comparing unit 22 has the signalsetting operation unit 23 provide the signal set value Mb having the amplitude value not larger than 1 but larger than 0 (for example 0.1) to signal comparingunit 25.Signal comparing unit 25 compares the triangular wave Tb with the signal set value Mb, performs PWM control, and the pulse signal PSb shown in FIG. 11D is output to AND operatingunit 26. - At this time, if the pulse width of pulse signal PSb is larger than the pulse signal PSa as shown in FIG. 11D, a pulse signal PSc similar to pulse signal PSa is output to
gate drive unit 27 as a result of the AND operation. In this state, the output voltage Vout1 ofbooster unit 2 is higher than the input voltage range Vref1 of DC/AC inverter 60 (Vout1>Vref1),voltage comparing unit 22 has the signalsetting operation unit 23 input the signal set value Mb of the value larger than the last amplitude value, to signal comparingunit 25. The triangular wave Tb and the signal set value Mb are compared bysignal comparing unit 25 and PWM control is performed. In this manner, pulse signal PSb is input fromsignal comparing unit 25 to AND operatingunit 26. - As a result, a pulse signal PSb having such a pulse width as shown in FIG. 11D is input to the AND
operating unit 26, and when the pulse width of pulse signal PSb is smaller than the pulse signal PSa, AND operatingunit 26 outputs a pulse signal PSc similar to the pulse signal PSb togate drive unit 27 as shown in FIG. 11F. As a result, the control is switched from the control to keep boosting ratio constant to the control in which the boosting ratio α is made smaller, that is, to a constant voltage control by which the output voltage ofbooster unit 2 is set within the tolerable input voltage range of DC/AC inverter 60. At this time, control target is to make constant the output voltage. - When the output voltage exceeds the input voltage range of DC/
AC inverter 60 while thebooster unit 2 performs the constant voltage control, that is, even when the boosting ratio a is made smaller and an overvoltage state occurs as it is impossible to further reduce the boosting ratio α, theinput breaker 8 b is tripped, so that a line to thesolar cell string 1 b is opened. More specifically, tripsignal generating unit 28 monitors the output voltage Vout2 as shown in FIG. 8. When the output voltage Vout2 becomes larger than a preset tolerable input voltage range Vref2 of DC/AC inverter 60 (Vref1<Vref2) (Vout2>Vref2), a trip signal Tp is sent from tripsignal generating unit 28 to inputbreaker 8b, andinput breaker 8 b is tripped, opening the path to thesolar cell string 1 b. - When switching
device 10 is short-circuited, short-circuit current flows betweensolar cell string 1 b and switchingdevice 10. When the short-circuit current flows, the temperature of switchingdevice 10 increases. If the short-circuit current flows continuously, the temperature of switchingdevice 10 will be much increased, possible resulting in malfunction ofbooster unit 2. Therefore, tripsignal generating unit 28 monitors the temperature Ts of switchingdevice 10 through a temperature sensor 29 attached to switchingdevice 10. When a set temperature is reached, tripsignal generating unit 28 transmits an input breaker trip signal Tp to tripinput breaker 8 b, so that the path to thesolar cell string 1 b is opened. In this manner, continuous flow of the short-circuit can be intercepted. - When a short-circuit current flows on the output side of
booster unit 2, that is, to the side of DC/AC inverter 60, malfunction of switchingdevice 10 or the like is possible. Therefore, fuse 12 provided in the preceding stage ofcapacitor 13 in boostingapparatus 3 is blown off, preventing continuous flow of the short-circuit current. - As switching
device 10 ofbooster unit 2 shown in FIG. 8, an FET (Field Effect Transistor), an IGBT (Insulated-Gate Bipolar Transistor) or the like may be used.Control circuit 15 may be implemented by an analog circuit or a digital circuit. - FIGS. 12A to12C show appearance of the box containing the booster unit in accordance with one embodiment of the present invention. FIG. 12A is a front view, 12B is a side view and 12C is a bottom view. FIGS. 13A and 13b show internal structure of the box shown in FIGS. 12A to 12C. FIG. 13A is a front view with the cover of FIG. 12B removed, and FIG. 13B is a bottom view. FIGS. 14A and 14B show the structure of the lid member shown in FIG. 12A. FIG. 14A is a front view of the lid, and FIG. 14B is a cross section showing how the lid is attached.
-
Box 30 shown in FIGS. 12A to 12C accommodatesbooster unit 2 shown in FIG. 8 and, as shown in FIG. 12B, the box is placed vertically along awall surface 40 outdoors.Box 30 includes abody portion 31 and acover 32 covering the same. As shown in FIG. 13A, abarrier portion 33 serving as a drainage path is formed along the top and side surfaces in thebody portion 31.Barrier portion 33 guides rain water penetrating betweenbody portion 31 and cover 32 to a lower portion ofbody portion 31, and discharges the water to the outside through arain outlet 34 as a discharge outlet, formed at the lower portion ofbody portion 31. Thus, conductive portions of boostingapparatus 3 andcontrol circuit 15 accommodated in thebody 30 placed outdoors are protected from rain water. - On the lower portion (right side of FIG. 12B) of
body portion 31 ofbox 30, aheat sink 35 is attached. Onheat sink 35, switchingdevice 10 in boostingapparatus 3 andbackflow preventing diodes device 10 in boostingapparatus 3 and bybackflow preventing diodes - Further, a
metal plate 41 having a rectangular shape with one side opened is provided surrounding theheat sink 35. Inside themetal plate 41, ahook 42 is formed to hold thebody portion 31. Asmetal plate 41 is attached to wallsurface 40 andbody portion 31 is held byhook 42,box 30 can be attached in the vertical direction along thewall surface 40.Metal plate 41 is formed to coverheat sink 35, so as to prevent burning by accidentally touching theheat sink 35 which is heated by the heat generated by the loss frombackflow preventing diodes device 10 when boostingapparatus 3 is in operation. - There is an
indicator unit 36 at the central portion ofcover 32 ofbox 30. When boostingapparatus 3 is activated,indicator unit 36 is turned on, and when the operation of the apparatus stops, it turns off. Thus, whetherbooster unit 2 is in operation in the day time with much sunlight or not can be confirmed without the necessity to open the body ofbooster unit 2. For example, if the indicator unit is off in the day time, it can be noticed that boostingapparatus 3 is not in operation. Therefore, whetherbooster unit 2 operates normally or not can be confirmed by theindicator unit 36. - Further, a
lid portion 37 is provided at a lower portion ofcover 32 to cover an opening portion. When removed frombody 31, thelid portion 37 allows operation ofinput breakers body 31, as shown in FIG. 13A. An attachment rail portion 38 is formed on one side oflid portion 37 as shown in FIG. 14A, and a fitting 39 is attached on the other side. Awater proof member 45 such as rubber is adhered at the contact portion betweenlid portion 37 andbody 31. - Fitting39 has a fixing
plate 391 andknob 392. Whenknob 392 is rotated, fixingplate 391 rotates and by this operation, it is possible to attach and detach thelid portion 37 to and from the body ofbooster unit 2. Whenlid portion 37 is opened, it is possible to operateinput breakers booster unit 2,input breakers lid portion 37. Further, no screw is used at thelid portion 37. Therefore, it is unnecessary to use a special tool to removelid portion 37 frombox 30. Therefore, it is possible to easily disconnectbooster unit 2 andsolar cell 1 b or DC/AC inverter 60 in case of emergency, for example, and therefore safety of the overall system can be improved. - As described above, according to the present embodiment, a space for installation dedicated for interconnection inside and outside of a building is saved as regards the connection between the DC power source such as
solar cell strings booster unit 2 and the DC/AC inverter 60, thededicated box 30 is integrated to reduce the cost of the overall apparatus, appearance inside and outside of the building is not spoiled as lines and wires for interconnection are reduced. Further, whenbooster unit 2 is in operation, overvoltage to DC/AC inverter 60 is prevented and generation of a short-circuit current in case of malfunction or short circuit of switchingdevice 10 can be intercepted, thus a safe apparatus is realized. - Further, a boosting circuit boosting the DC power voltage, a backflow preventing circuit preventing backflow of current from the boosting means to the DC power source, an input connecting/disconnecting unit for connecting or disconnecting the DC power source to and from the boosting circuit, and a lightning surge preventing circuit preventing entrance of lightning surge from the DC power source to the boosting circuit are provided, so that backflow of current from the boosting apparatus and the inverter apparatus to the solar cell can be prevented and it is possible to safely connect or disconnect the solar cell and the boosting circuit and the boosting circuit and the inverter apparatus, at the time of engineering work, for example.
- Further, entrance of lightning surge from the solar cell side to the boosting circuit and the inverter apparatus in case of thunderbolt can be prevented, and therefore safety of the inverter apparatus is ensured. Further, a DC power having the same DC voltage as that of standard solar cell string can be supplied even from a substandard solar cell string to the inverter apparatus, and therefore limited space of a building roof, for example, can be efficiently used.
- Further, when the output voltage of the booster unit is lower than the upper limit set voltage, boosting circuit performs the control to make constant the boosting ratio, so that a DC power comparable to that of a standard solar cell string can be supplied from a substandard solar cell string to the inverter apparatus. Therefore, a limited space of a building roof, for example, can be efficiently utilized.
- Further, when the output voltage of the booster unit is higher than the upper limit set voltage, the boosting circuit performs control to make constant the upper limit voltage, and therefore overvoltage to the inverter apparatus possibly causing a malfunction can be prevented.
- When the boosting circuit is in operation in the day time with high amount of sunshine, control is performed to make constant the boosting ratio, and when the output voltage increases to be higher than the upper limit set voltage, the control to keep constant the boosting ratio is stopped and control is performed to keep constant the upper limit voltage by changing the boosting ratio, so that the output voltage does not exceed the upper limit. In this manner, overvoltage to the inverter apparatus possibly causing a malfunction can be prevented.
- Further, trip signal generating circuit generates a trip signal when the output voltage becomes excessive, so that connection to the substandard solar cell string is opened by the opening circuit. While the booster unit is in operation in the day time with high amount of sunshine and control is performed to keep constant the boosting ratio or keep constant the voltage, the trip signal generating circuit trips and opens the circuit when an overvoltage is detected by the boosting circuit. Therefore, over voltage to the inverter apparatus possibly causing a malfunction can be prevented.
- As to the trip function in the breaker, when the booster unit is in operation in the day time with high amount of sunshine, boosting circuit is short-circuited, a short-circuit current flows between the solar cell and the boosting circuit and the temperature of the boosting circuit increases, then the trip signal generating circuit generates a trip signal to open the circuit when the temperature increase is larger than the set value. Consequently, continuous flow of the short-circuit current is prevented, and hence malfunction of the booster unit caused by the short-circuit current can be prevented.
- The boosting circuit includes a fuse for intercepting the short-circuit current from the output side. Therefore, when the inverter apparatus is short-circuited, the short-circuit current flows from the inverter apparatus to the booster unit and the short-circuit current flows in the circuit, the fuse operates to open the circuit and prevents continuous flow of the short-circuit current. Therefore, malfunction of the booster unit caused by the short-circuit current can be prevented.
- The fuse is connected in series with the boosting circuit, and the path through which the short-circuit current flows is opened in accordance with the magnitude of the short-circuit current. Therefore, when the inverter apparatus is short-circuited and the short-circuit current flows from the inverter apparatus to the booster unit and the short-circuit current flows in the circuit, the fuse provided in the boosting circuit is blown off, opening the circuit. Thus, continuous flow of the short-circuit current can be prevented, and malfunction caused by the short-circuit current can be prevented.
- Further, at least the input/output terminal is accommodated in a box placed outdoors, and the box includes a drainage path guiding the rain water to the lower portion when the rain water penetrates and a discharge outlet for discharging the rain water guided to the lower portion to the outside. Therefore, entrance of the rain water to the conductive portions of the inverter apparatus and the control circuit can be prevented. Further, as a dedicated box is formed integrally, the cost of the overall apparatus can be reduced.
- Further, a radiator for generation of heat from the boosting circuit and the backflow preventing circuit to the outside is provided on the outside of the box. Thus, the effect of radiation can be enhanced.
- Further, as a metal plate covering the radiator of the box and supporting the box on the wall surface is provided, possibility of burning by accidentally touching the radiator can be prevented and the box can be attached on a wall surface.
- Further, a lid portion that can be opened is provided on the box, and by operating the input connecting/disconnecting unit with the lid opened, it is possible to separate the booster unit from the DC power source in case of emergency.
- Further, an indicator means that turns off when the boosting circuit is driven and turns off when the operation of the boosting circuit stops is provided on the box. Therefore, it can be readily confirmed whether the boosting circuit is normally operating or not.
- Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims.
Claims (22)
Applications Claiming Priority (5)
Application Number | Priority Date | Filing Date | Title |
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JP2000129865A JP3553462B2 (en) | 2000-04-28 | 2000-04-28 | Photovoltaic power generation system and boost unit used for it |
JP2000-129865(P) | 2000-04-28 | ||
JP2000-129865 | 2000-04-28 | ||
JP2000-230790 | 2000-07-31 | ||
JP2000230790A JP3638861B2 (en) | 2000-07-31 | 2000-07-31 | Booster unit |
Publications (2)
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US20010035180A1 true US20010035180A1 (en) | 2001-11-01 |
US6448489B2 US6448489B2 (en) | 2002-09-10 |
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US09/842,923 Expired - Lifetime US6448489B2 (en) | 2000-04-28 | 2001-04-27 | Solar generation system |
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DE10120595A1 (en) | 2001-11-08 |
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