NL1018067C2 - Device for generating photovoltaic energy. - Google Patents

Abstract

Apparatus for generating photovoltaic energy, comprising a number of photovoltaic modules for generating electric power, wherein each module is connected to an energy transmitter which can be coupled in high-frequency electromagnetic manner, a central circuit which can be coupled to the mains, and at least one power cable connected to the central circuit and provided with branches, wherein each branch is connected to an energy receiver which can be coupled in high-frequency electromagnetic manner for coupling to one of said energy transmitters, and wherein each energy receiver is provided with a rectifier circuit.

Description

DEVICE FOR GENERATING PHOTOVOLTAIC ENERGY

The invention relates to a device for generating photovoltaic energy, comprising a number of photovoltaic modules for generating electrical power, wherein each module is connected to a high-frequency electromagnetically connectable energy supplier, a central circuit which can be connected to the mains, and at least one power cable connected to the central circuit and provided with branches, each branch being connected to a high-frequency electromagnetically connectable energy receiver for coupling to one of said energy providers.

Such a device was described during the 16th European PV Conference and Exhibition, Glasgow, UK, May 1, 2000 by I. Weiss et al. The aim of this modular device was to reduce the installation costs of a photovoltaic energy generation system and to extend the service life. of such systems. However, the described device has the disadvantage that it is sensitive to electromagnetic interference that may occur in the couplings between respective energy generators and receivers.

It is an object of the invention to provide a photovoltaic energy generation system that is easy to install, that can be produced at a relatively low price, and that is in use insensitive to climate influences, electromagnetic interference and other disturbances.

This object is achieved with a device of the type described in the preamble, wherein according to the invention each energy receiver is provided with a rectifier circuit.

In an embodiment of a device according to the invention, each module is connected to the energy provider via a maximization circuit for maximizing the power to be transmitted by the module.

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The maximization circuit comprises, for example, a current converter connected to the module, a control circuit for the current converter and a maximum power follower circuit (MPP tracker) connected to the module, an output of the current converter being connected to the energy transmitter, an output of the maximum power follower circuit being connected to a first input of the control circuit, and wherein the output of the current converter is connected to a second input of the control circuit, which control circuit lowers or increases the output current of the current converter upon a decrease or increase of the power generated by the module, independently of the value of the output voltage of the current converter.

With such a maximization circuit it is achieved that the power generated by the module is supplied by the current converter via the energy generator and the energy receiver to the power cable, the operation of that current converter being independent of the voltage on that cable.

In one embodiment, the current transformer, in operation when a predetermined value of the output voltage is exceeded, forms a voltage source.

In this embodiment the voltage of the power cable is limited to a predetermined maximum value.

In a device according to the invention, the rectifier circuit in each tap is preferably provided with a noise filter.

In one embodiment, the energy generators and the respective energy receivers 30 each comprise a high-frequency coil with a ferrite core separated by an air gap, the air gap being surrounded by a short-circuit winding of an electrically conductive material.

In a device according to the invention, the central circuit comprises a direct current / alternating current converter (DC / AC-inverter).

In one embodiment, the central circuit comprises measuring *> 1 »··. ·. and control means for respectively measuring the input voltage and increasing or decreasing the amount of electrical power to be transmitted to the mains with a measured increase or decrease in the input voltage.

The central circuit comprises, for example, an H-bridge circuit for converting said input voltage into the mains voltage at a predetermined maximum value of the input voltage, which maximum value is higher than the amplitude of the mains voltage.

A device according to the invention further comprises a data bus for data transport, wherein the data transport between the energy providers and the respective energy receivers takes place, for example, by means of a high-frequency electromagnetic coupling, or by means of a capacitive coupling, which is advantageously provided by a centering pen.

The invention will be elucidated hereinbelow on the basis of exemplary embodiments, with reference to the drawings.

Show in the drawings

FIG. 1 a block diagram of an embodiment of a device according to the invention,

FIG. 2 is a block diagram of an energy provider with a maximization circuit for a device shown in FIG. 1 in more detail,

FIG. 3 is a block diagram of an energy receiver with rectifier and filter for a device shown in FIG. 1 in more detail, and FIG. 4 is a block diagram of a central circuit for a device shown in FIG. 1 in more detail.

Corresponding components are designated in the drawings with the same reference numerals.

FIG. 1 shows a modular system 1 with solar panels 2 placed in the outside air 35 for generating electric power, wherein each solar panel 2 is provided with a built-in high-frequency electromagnetic energy provider 3, 4 which is high-frequency electromagnetically coupled to a high-frequency electromagnetic energy receiver 8, which is coupled at its output to the input of a rectifier 9, which is connected at its output to a branch 7 of a moisture-tight ("sealed") DC cable 6 which leads via a transition 10 (for example in a roof or a wall) to a central converter 5 which is arranged in an indoor environment. In the central converter 5, which controls the direct voltage on the cables 6 so that it is higher than the peak voltage of the mains 4, the direct current supplied by the cables 6 is converted into an alternating current and supplied to the mains 4.

FIG. 2 shows an energy transmitter 3 which is connected to a solar panel 2 via a maximizing circuit 11, 12, 13. The maximizing circuit 11, 12, 13 comprises a current converter 11 connected to the solar panel 2, an output of which is connected to the energy transmitter 3, a control circuit 12 for the current converter 11, and a maximum power follower circuit 13 connected to the solar panel 2 (MPP tracker), wherein an output of the MPP tracker 13 is connected to a first input of the control circuit 12 and the output of the current converter 11 is connected to a second input of the control circuit 12. The MPP tracker 13 is a circuit known per se that seeks the maximum power of the solar panel 2 and sends this information to the control circuit 12, which controls the current converter 11 in such a way that it delivers a larger output current with increasing power supplied by solar panel 2 and delivers a smaller output current with decreasing power. In order to ensure that the current converter 11 acquires the character of a current source, information about the output current I is fed back to the control circuit 12. This ensures that the current converter 11 transmits the power supplied by the solar panel 2 to the power cable 6 via an electromagnetic coupling 35 and, at the same time, is independent of the voltage on that cable 6. If the voltage on the cable 6 rises above the normal operating range, the character of a current source is abandoned and the current converter 11 acquires the character of a voltage source, so that the voltage on the cable 6 is limited to a certain maximum value. To achieve this, information about the output voltage U is fed back to the control circuit 12. The energy transmitter 3 is, for example, the primary winding of a pot-core ferrite transformer with a short-circuit winding of conductive material, for example copper or aluminum, around the air gap (represented by dotted line 14) is wrapped. This short-circuit winding can fulfill a dual function if it also acts as a shield. If the pot core is provided with a trim hole, this can be used for a centering pin, which for safety reasons is preferably arranged in the non-net-coupled part. The pot core is preferably completely sealed to prevent corrosion. The power cable 6 is preferably electrically insulated by a winding with a so-called triple coated wire. The figure further shows a circuit for data communication 15 with data bus 16.

Data communication can take place directly via the magnetic coupling by means of a modulated carrier wave, or via a capacitive coupling. In the case of a capacitively coupled data transport, use can optionally be made of a aforementioned centering pin, which thus acquires a dual function.

FIG. 3 shows an energy receiver 8 which can be coupled to the energy transmitter 3 shown in FIG. 2 and which comprises a rectifier circuit 9 and a filter 17 for electromagnetic interference, a so-called EMI filter. The figure further shows a data bus 16.

FIG. 4 shows the central circuit 5 of FIG. 1 in more detail. The central circuit 5 comprises an energy buffer 18 in the form of an electrolytic capacitor for buffering a power ripple (with in this case a frequency of 100 Hz) at the occurring mains frequency (in this case 50 Hz), and a central DC / AC inverter 19, designed as pulse width modulation (PWM) H-bridge that outputs a sinusoidal current 1: Λ Ί Λ 7 6 to the mains 4. The central DC / AC inverter 19 keeps the voltage on the direct-current cable 6 (the bus voltage) constant. This value is preferably chosen to be so high (for example 385 V dc) that the required mains voltage 5 (for example 230 V ac) can be made directly through the H-bridge 19, without interruption of a boost converter or other additional circuits. With decreasing power consumption by the mains 4, the bus voltage will rise, as a result of which the current converters 11 on the solar panels 2 will act as a voltage source in a protection mode, and consequently limit the bus voltage to a predetermined value that is above the normal value of the bus voltage. The figure further shows a circuit 20 for data communication.

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Claims (13)

Device (1) for generating photovoltaic energy, comprising - a number of photovoltaic modules (2) for generating electrical power, wherein each module (2) is connected to a high-frequency electromagnetically connectable energy supplier (3), - a central circuit (5) connectable to the mains (4), and - at least one power cable (6) connected to the central circuit (5) and provided with branches (7), each branch (7) being connected to a high-frequency electromagnetically connectable energy receiver (8) for coupling to one of said energy providers (3), characterized in that each energy receiver (8) is provided with a rectifier circuit (9). Device (1) according to claim 1, characterized in that each module (2) is connected to the energy generator (3) via a maximization circuit (11, 12, 13) for maximizing the voltage across the module (2) 20 load capacity. Device (1) according to claim 2, characterized in that the maximization circuit is a current converter (11) connected to the module (2), a control circuit (12) for the current converter (11) and one connected to the module (2) 25 comprises a maximum power follower circuit (13) (MPP tracker), wherein an output of the current converter (11) is connected to the energy generator (3), an output of the maximum power follower circuit (13) is connected to a first input of the control circuit (12) and wherein the output of the current converter (11) is connected to a second input of the control circuit (12), which control circuit (12) lowers or increases the output current of the current converter (11) with a decrease or increase in the module (2)?, ^ 9 ^ r »I 1 t Ί - \ J» generated power, independent of the value of the output voltage of the current converter (11). Device (1) according to claim 3, characterized in that the current converter (11) forms a voltage source in operation when a predetermined value of the output voltage is exceeded. Device (1) according to one of claims 1 to 4, characterized in that the rectifier circuit (9) is provided with a noise filter (17) in each tap. Device (1) according to one of claims 1 to 5, characterized in that the energy facade (3) and the respective energy receivers (8) each have a high-frequency coil separated by an air gap (14) with a ferrite core, wherein the air gap (14) is surrounded by a short-circuit winding of an electrically conductive material. Device (1) according to one of claims 1 to 6, characterized in that the central circuit (5) comprises a direct current / alternating current converter (19) (DC / AC inverter). Device (1) according to claim 7, characterized in that the central circuit (5) comprises measuring and control means for respectively measuring the input voltage and increasing or decreasing the amount to be transmitted to the mains (4) electrical power with a measured increase or decrease in the input voltage. 9. Device (1) according to claim 8, characterized in that the central circuit (5) comprises an H-bridge circuit (19) for the maximum value of the input voltage at a predetermined maximum value of the input voltage, which maximum value is higher than the amplitude of the mains voltage, converting that input voltage into the mains voltage. Device (1) as claimed in any of the claims 1-9, characterized in that it comprises a data bus (15, 16, 20) for data transport. Device (1) according to claim 10, characterized in that the data transport between the energy providers (3) and the respective energy receivers (8) takes place by means of a high-frequency electromagnetic coupling. Device (1) according to claim 10, characterized in that the data transport between the energy providers (3) and the respective energy receivers (8) takes place by means of a capacitive coupling. Device (1) according to claim 12, characterized in that the capacitive coupling is provided by a centering pin. 1! ! · '·' 7 Y 'Y y X, l