WO2010063913A2

WO2010063913A2 - Electrical power supply device, and equipment for controlling breaker that includes such device

Info

Publication number: WO2010063913A2
Application number: PCT/FR2009/052170
Authority: WO
Inventors: Franck Guillon; Julien Schutz
Original assignee: Societe Dauphinoise De Constructions Electro-Mecaniques
Priority date: 2008-12-01
Filing date: 2009-11-10
Publication date: 2010-06-10
Also published as: WO2010063913A3; FR2939248A1; FR2939248B1

Abstract

The present invention relates to a power supply device (1) for generating DC voltage to a load (22) and comprises: - a photovoltaic power source (2); - a storage battery (8) connected to the output terminals (4, 5) of the photovoltaic source (2); - a DC-DC converter (10), the input terminals (11, 42) of which are connected to the terminals (6, 7) of the storage battery (8) and the output terminals (13, 14) of which are connected to the load (22). The invention is characterized in that it also includes a supercapacitor (30), the terminals of which are connected to the output terminals (13, 14) of the converter (10) in parallel on the load (22).

Description

POWER SUPPLY DEVICE, AND INSTALLATION OF

CONTROLLING A DISCONNECT INCLUDING SUCH A DEVICE

Technical area

The invention relates to the field of autonomous power supply devices, intended to supply energy to various electrical appliances. It finds a particular application for the supply of electromechanical equipment, and in particular disconnectors and other devices for cutting or reconfiguring electrical circuits.

Thus, in the following description, the invention will be described in more detail in the application of the disconnector control, but it covers other applications operating on the same principle.

Previous techniques

In general, the disconnectors may be located in areas where the low voltage power supply may be interrupted or nonexistent. However, it is essential to operate a disconnector that a power source is available to be able to move the moving parts, when the reconfiguration of a circuit is necessary.

Various solutions can be envisaged to benefit from an autonomous source of energy, with varying degrees of flexibility of use. Thus, the use of generators can be envisaged, to produce electrical energy from a heat engine. However, the fuel supply and management of the latter poses obvious logistical problems. In addition, such solutions are not possible under certain climatic conditions.

Another solution is to use an electrical energy generation device operating from photovoltaic panels. Thus, in a conventional manner, there are power sources that include a panel of photovoltaic cells converting solar energy into an electrical voltage, itself applied to the terminals of a storage battery. A DC / DC converter provides a regulated voltage from the voltage at the terminals of the storage battery.

This solution, however, has drawbacks in that the storage batteries are highly stressed in cases of significant consumption. However, in the case of disconnector control, the currents taken from the battery are important for very short periods corresponding to the phases of movement of the movable members. The rest of the time, the batteries are not solicited.

Consequently, the solutions that can be envisaged today require oversizing of the batteries, which is economically detrimental. Conversely, undersizing batteries inevitably leads to premature wear thereof, which causes significant maintenance costs.

In the document "A stand-alone photovoltaic supercapacitor battery hybrid energy storage system" POWER ELECTRONICS AND MOTION CONTROL CONFERENCE, 2008, EPE-PEMC 2008. 13 TH, IEEE, PISCAT AWAY, NJ, USA, a combined system, in which a photovoltaic panel delivers energy through a first converter. A second converter connected at the output of this first recharges a storage battery and a super-capacitor. The problem with this type of configuration is that the currents consumed by the load pass through this second converter with impacts on the dimensioning of the components of the latter.

The object of the invention is to provide a solution which is easy to implement, which has a high reliability, and which allows a reasonable dimensioning of the storage battery, so as not to unreasonably increase the cost of storage. 'an installation.

Presentation of the invention

The invention therefore relates to a power supply device for delivering a DC voltage to an electrical load. In a conventional manner, this device comprises:

"a source of photovoltaic energy,

"A storage battery connected to the terminals of the power source," a DC / DC converter, whose input terminals are connected to the terminals of the storage battery and the output terminals are connected to the load.

According to the invention, this device is characterized in that it also comprises a super-capacitor whose terminals are connected to the output terminals of said converter, so that the super-capacitor is in parallel with the load.

In other words, the invention consists in using a super-capacitor which makes it possible to store energy during the phases in which the photovoltaic elements are active and produce energy. Thus, this super-capacitor makes it possible to deliver the energy, and in particular the strong currents that are taken during the phases of consumption of the load. In this way, the energy is provided, in a preferred manner, by the super-capacitor and not by the accumulator battery, which makes it possible to limit the wear of the latter over time. The management of the converter located downstream of the storage battery makes it possible to isolate the accumulator battery from the charge so that the phases of consumption by the charge do not draw any current on the accumulator battery, which increases thus the life of the latter.

In addition, the number of charging and discharging cycles of a super-capacitor can be very high, of the order of several hundreds of thousands of cycles, without any real impact on the reliability of the installation.

The super capacitors have the advantage of being able to be discharged almost completely without modification of their electrical characteristics, while conversely, deep discharges imposed on the storage batteries inexorably cause the degradation of their electrical properties.

Thus, thanks to the invention, the storage battery can be dimensioned particularly reduced and optimized. In practice, the DC / DC converter can be a voltage booster, allowing for example to use a standard battery of 12 volts, compatible with the most widespread photovoltaic panels, to generate a voltage generally of the order of 48 Volts, frequently used in electrical control devices, particularly disconnectors.

Advantageously in practice, the device comprises an electronic control unit, ensuring the management of the operation of the converter. This unit makes it possible in particular to activate the converter when the voltage across the super capacitor drops below a predetermined threshold.

In other words, when the load has consumed energy that causes the voltage across the super-capacitor to have substantially decreased, the converter will start to recharge the super-capacitor. This recharging is done primarily directly from the photovoltaic panel when it is operational, or even from the battery when the photovoltaic panels are not in production situation.

In practice, the invention makes it possible to use low capacity storage batteries compared to traditional solutions. This low capacity is evaluated with respect to a capacity of the super-capacitor.

Thus, in practice, preference is given to sizing in which the ratio C x U / K is greater than 40 for which: "C is the capacity of the super-capacitor expressed in Farads,

"U is the output voltage of the DC converter, expressed in

Volts; "K is the capacity of the storage battery, expressed in Ampere: hour.

Advantageously, in practice, the power supply device may also include a device for regulating the charge of the battery from the photoelectric energy delivered by the photovoltaic power source. Such a system makes it possible in particular to avoid the overcharging of the storage battery when the photovoltaic panel continues to produce energy. In practice, the capacity of the super-capacitor is typically greater than ten Farads, for a nominal voltage of 48 volts plus or minus 5%.

As already mentioned, the invention relates to a control installation of an electrical disconnector including an electric motor actuating the movable members of the disconnector, and an electrical control unit ensuring the control of said motor.

This installation is characterized in that the motor and the electrical control unit are powered by a supply device as described above.

Brief description of the figures

The manner of carrying out the invention as well as the advantages which result therefrom will emerge from the description of the embodiment which follows, in support of the appended figures in which: FIG. 1 which is a simplified electrical diagram showing the various main organs intervening in the invention; Figures 2 to 5 are diagrams similar to Figure 1, showing different phases of operation of the system.

Way of realizing the invention

As can be seen in FIG. 1, the power supply device 1 comprises a photovoltaic panel 2, typically delivering a voltage of 12 volts with a nominal power of 20 watts. This photovoltaic panel 2 is connected to a charge control device 3 or charger, whose output terminals 4, 5 are connected to terminals 6 and 7 of an accumulator battery 8.

This battery has a nominal voltage of the order of 12 volts, and a capacity of about 12 amperes / hour.

At the terminals 6, 7 of the battery 8 is connected a static DC / DC converter 10. The input terminals 11, 12 of the converter are therefore directly connected to the output terminals 4, 5 of the charger 3, so that the converter 10 is powered directly by the photovoltaic panel 2, when the latter is operational. The output terminals 13, 14 of the static converter 10 are connected to the terminals 20,

This load is, in the case of a disconnector control installation, constituted by the electric motor ensuring the movement of the moving parts of the disconnector, and the electronic control unit controlling the motor.

Conventionally, the motors conventionally used for the control of disconnectors operate at nominal voltages of 48 volts, but the invention is in no way limited to these values, nor even to the nominal values of 12 volts stated for the photo panel voltaic and the storage battery.

According to the invention, a super-capacitor 30 is arranged in parallel with the load 1, between the output terminals 13, 14 of the converter 10.

An electronic control unit 38 provides supervision and management of the entire power supply device. Thus, this control unit manages the voltage converter 10, and the management of the charge controller device 3.

The actuation of the feeding device is as follows.

As illustrated in Figure 2, when the system is at rest, that is to say that the load 20 does not consume energy, and that the photovoltaic panels 2 are not operational, for example because of a too low brightness, no current flows through the converters 3 and 10, and the load is maintained across the battery 8 and the super-capacitor 30.

As illustrated in FIG. 3, in the presence of light energy, the photovoltaic panel 2 supplies the storage battery 8 with a suitable current I _B , controlled by the converter 3 by means of a remote control 38. This current I _B is limited to avoid damaging the battery charge.

More specifically, the device 3 charge controller monitors the charge of the battery 8 to prevent overload and degradation of the latter. Thus, in the framework of power generation by the photovoltaic panel while the battery 8 is already correctly charged, the charge control device 3 interrupts the charging of the battery.

As illustrated in FIG. 4, when the load 20 is in operation, it consumes a current I _I which is only supplied by the supercapacitor 30, the converter 10 being controlled so as not to deliver current and in particular not to pick it up. on the storage battery 8. It should be noted that the duration of the phases of consumption by the load, in the application to the control of disconnector motors, is relatively low, of the order of a few seconds, at worst a few dozens of seconds. During these phases, the current consumed on the supercapacitor may be of relatively high intensity.

After one cycle of operation of the load 20, the converter 10 is used to recharge the super-capacitor 30. This recharging can be done either from the energy produced by the photovoltaic panel 2, or even more steadily by the storage battery 8, whose availability is permanent. The converter 10 draws a calibrated current of low intensity compared to that taken by the load 20 (at the voltage rise ratio near the converter 10). The recharging phase of the super-capacitor 30 is therefore performed in a longer time than the operation of the load 20, but largely compatible with the respective periods of use.

Moreover, the static converter 10 makes it possible to increase the output voltage of the battery in order to deliver to the super-capacitor a higher voltage, corresponding to the rated operating voltage of the load.

This converter 10 is managed by the control unit 38 whose role is to correctly maintain the charge of the super-capacitor, and prevent its degradation, in particular by excessive overload. The control unit 38 also operates a charge management of the super-capacitor. Thus, it can be done only if the battery charge level (or the voltage level) is sufficient, which makes it possible to guard against a possible discharge of the battery which could lead, if the level discharge was too important, to damage or even destroy the battery. This system thus also allows to protect the battery by the management via the control unit 38, the load or not the super-capacitor depending on the voltage level of the battery.

When the load 22 has consumed an energy which makes the super-capacitor's electrical charge fall below a predetermined threshold, and in the absence of sunlight, it is the accumulator battery 8 which supplies the supercapacitor with the appropriate management of the up-converter 10. In other words, the super-capacitor 30 provides power to the load, particularly for high current demands.

In this way, the above that the device according to the invention allows to use a battery of relatively low capacity, thus having a lower weight and reduced cost. Similarly, since the strong currents are provided by the supercapacitor, the battery undergoes a lower wear over time, and thus sees its increased lifetime, typically a multiplicative factor greater than 3. In addition, the number of charge and Sudden discharge by the super-capacitor can reach several hundreds of thousands without degradation of its electrical properties, and thus itself excessive consumption on the accumulator battery.

Claims

1 / Power supply device (1) for supplying a DC voltage to a load (22), comprising: "a source of photovoltaic energy (2),

"an accumulator battery (8) connected to the output terminals (4,5) of the photovoltaic source (2),

a DC / DC converter (10) whose input terminals (11, 42) are connected to the terminals (6, 7) of the storage battery (8), and the output terminals (13, 14) are connected to the load (22), characterized in that it also comprises a super-capacitor (30) whose terminals are connected to the output terminals (13, 14) of the converter (10), in parallel with the load (22). ).

2 / Apparatus according to claim 1, characterized in that the converter (10) DC / DC is voltage booster.

3 / Apparatus according to claim 1, characterized in that it comprises an electronic control unit (28) providing management of the operation of the converter (10).

4 / Apparatus according to claim 1, characterized in that the converter (10) is activated when the voltage across the super-capacitor (30) passes below a predetermined threshold.

5 / Apparatus according to claim 1, characterized in that the C.U / K ratio is greater than 40, where:

• C has the capacity of the super-capacitor (30), expressed in Farad; "U is the nominal output voltage of the converter (10), expressed in volts," K is the capacity of the accumulator battery (8), expressed in amperes. hour,

6 / Apparatus according to claim 1, characterized in that it comprises a device (3) for regulating the charge of the accumulator battery (8) from the electrical energy delivered by the photovoltaic energy source (2). 11 Device according to claim 1, characterized in that the capacity of the supercapacitor (30) is greater than 10 farads, for a nominal voltage of 48 volts, +/-

5%.

8 / Control installation of a disconnector, including an electric motor operating the movable members of the disconnector, and an electrical control unit ensuring the control of said motor, characterized in that said motor and said electronic control unit are powered by a device according to claims 1 to 7.