FR3039721A1 - CURRENT DISTRIBUTION METHOD PRODUCED BY PHOTOVOLTAIC PANELS - Google Patents

Abstract

Method for managing the current produced by an installation of photovoltaic panels (2) comprising electrical appliances (5, 6, 7) having different powers, these appliances being on the one hand electrically connected to a supplier's supply network and secondly to the installation of photovoltaic panels, this process being characterized in that when the electrical production by the photovoltaic panels reaches a minimum production threshold, at least one of the electrical appliances is allowed to be supplied with current ( I) produced by the panels (2) and in parallel, for this electrical device, during this power supply, said device is forbidden to supplement its power supply by connecting to the supplier's supply network.

Description

CURRENT DISTRIBUTION METHOD PRODUCED BY PHOTO VOLTAIC PANELS. The invention relates to a current management method produced by a set of photovoltaic panels. It also relates to the means for the implementation of the method.

Photovoltaic installations are intended to produce power from a non-fossil source.

The instantaneous amount of current produced by a photovoltaic installation depends on the sensors (more or less efficient), the orientation of the said sensors (orientation of the roof of the house), its position on the globe (latitude) and the solar time.

The production of this current is not constant because it will grow and then decrease in the day and it is not reproducible from one day to another.

For a given installation, the production of current depends directly on the quantity of light it receives and therefore on the schedule knowing that at night, the installation can not supply power.

This current produced by the installation can be injected in full on the electricity network of the usual suppliers and therefore sold but it can be consumed by the owners.

The choice of the sale or the consumption is often the result of the price of the current bought by the suppliers and the selling price of the grid current but also other considerations.

In recent years, the selling price to suppliers has been decreasing, while the purchase price to suppliers is increasing. The self-consumption of the electric current has advantages but also disadvantages.

The first drawback is that the demand in current quantity (consumption) is different from the production.

For example in the evening we do not produce but we consume. At the beginning of the day or at the end of the day the sun shines less and the panels produce less.

During the sunniest period, you are at work and a priori the electricity needs of your home are reduced.

For almost all installations, during the period when consumption is more than production, external energy is used to satisfy the momentary need. When the system management system detects the ignition of the oven that consumes 3KW while the output is 2kW, it uses the 2kW of the installation and takes lkW on the network or takes the 3kW on the network and the 2KW products are sold.

To overcome this drawback, in particular the absence of current at night, storage batteries can be used to store energy when too much energy is produced and to restore it when demand is greater than production.

A disadvantage is that these batteries are bulky, expensive and have a limited life because a battery has a limited capacity of charge / discharge.

The management of the consumption of the current produces imposes obligations related to the variation of production.

Indeed, for example it is recommended to the users of materials consuming a lot of energy such as the washing machine, the dishwasher, the irons ... etc to use these apparatuses during a period ranging from 11 hours to 15 hours because it is a period normally sunny and therefore of high production. Time schedulers equip some of these machines but it is a predictive management with the vagaries of the weather.

Regarding the storage of electrical energy other than a battery, it is known to heat a water tank for bathing or showering by means of an electrical resistance. These tanks are commonly equipped with a 1.5kW or 2kW resistor.

Either we program the start-up when the power produced by the panels is 1.5 kW corresponding to the instantaneous need of the tank or as soon as we produce a minimum of current, for example 500W, we start the heating but the resistance is 1.5 kW, it will supply at the same time from the supplier to deliver the power of 1.5kW.

Thus, 1/3 of the current consumed is provided by the panels and the rest is acquired and invoiced by the supplier.

This principle of operation is the most commonly used and it is found that at the beginning of the afternoon, the water of the water supply being hot, it stops supplying the tank with current. The produced current is then available for the washing machine or the dishwasher or it is injected on the network. The object of the invention is to propose a better use of the current produced by the installation. To this end, the subject of the invention is a method for managing the current produced by an installation of photovoltaic panels comprising electrical appliances having different powers, these apparatuses being on the one hand electrically connected to a supply network of a supplier and on the other hand to the installation of photovoltaic panels, this process being characterized in that when the electrical production by the photovoltaic panels reaches a minimum production threshold below the maximum production threshold, at least one of the electrical appliances is authorized to be powered by the product current and in parallel, for this electrical device, during this power supply, the said device is forbidden to supplement its power supply by connecting to the supplier's supply network. The invention will be better understood from the following description given by way of non-limiting example with reference to the drawing which represents current distribution installation from photo voltaic panels.

Referring to the drawing, we see a facility 1 for producing electricity by means of photovoltaic panels 2.

The produced current can be self-consumed and / or sold to a supplier.

This installation comprises energy storage by heating a volume of water 3 by means of an electrical resistance. In general, the storage of energy consists of a large reserve of water used primarily for washing or dish washing. Other electrical appliances 5, 6, 7 are powered by the current I produced by the panels or by the current J supplied by a supply network of a supplier.

Each device has its electrical resistance of a power adapted to the function of said apparatus.

When the electrical production by the photovoltaic panels reaches a minimum production threshold (below the maximum production threshold), at least one of the electrical devices is allowed to be supplied with the product current I and in parallel, for this electrical appliance, during this period. power supply, the device is forbidden to supplement its power supply by connecting to the supplier's supply network.

Thus, when power is supplied to a resistor by the current produced by the photovoltaic panels 2, it is forbidden to feed the said resistor together with current supplied by a supplier. The control of Γ power supply resistance by the current from the photovoltaic panels cut Γ supply of said resistance by the network current or prevents its power supply.

Of course, by a voluntary command, it is possible to force prohibit resupply of resistance by the network and thus to allow the operation of the device.

Advantageously, for electrical appliances 5,6 reheating water during their operation, the said devices are equipped with a reserve 8, 9 of water with its own resistance adapted to its consumption and during operation of said apparatus is used already heated water instead of heating cold water.

For example, these appliances are a washing machine 5, a dishwasher 6, an iron, etc. These devices will have a reserve of water previously heated.

For each device, it establishes a minimum power below which the operation of said device can no longer be correct and only if the available power reaches the minimum power above that is allowed the operation of the device.

When power produced by the panels is available, before injecting it into the supply network of a supplier, the current is used to heat the reserve (s) of water if necessary.

Thus, the means for carrying out the method comprise a means 10 for measuring the power delivered by the photovoltaic panels for detecting a minimum power, electrical devices 5, 6, 7 electrically connected to the installation of photovoltaic panels 2, a supply network of a supplier, means 12 for authorizing the supply of at least one electrical appliance by the current coming from the photovoltaic panels and in parallel prohibiting the supply of said electrical appliance with power from the electricity network; supplier supply to complete the power.

A control means makes it possible to remove the prohibition of supplying the electrical apparatus with current from the network.

Electric appliances that in their operation heat a volume of water are equipped with a reserve of water with its appropriate resistance to heat the water with the current produced by the panels and store it in reserve.

Claims (5)

1. A method for managing the current produced by an installation of photovoltaic panels (2) comprising electrical appliances (5, 6, 7) having different powers, these appliances being on the one hand electrically connected to a supply network of a supplier and secondly to the installation of photovoltaic panels, this method being characterized in that when the electrical production by the photovoltaic panels reaches a minimum production threshold, at least one of the electrical appliances is allowed to be powered by the current (I) produced by the panels (2) and in parallel, for this electrical device, during this power supply, said device is forbidden to supplement its power supply by connecting to the supplier's supply network. 2. A method for managing the current produced by a photovoltaic panel installation according to claim 1 characterized in that for appliances (5,6) electric heating water during operation, it equips said devices a reserve (8,9) water having its own resistance adapted to its consumption for heating the water with the current produced by the panels and store it in reserve and during operation of said apparatus is used water already heated instead of heating cold water. 3 Process for managing the current produced by a photovoltaic panel installation according to claim 2, characterized in that, when power produced by the panels is available, before it is injected into the supply network of a supplier, it is used the current for heating the water reserve (s). 4 Installation comprising photovoltaic panels 2, electrical appliances 5, 6, 7 electrically connected to the installation of photovoltaic panels 2 and to a supply network of a supplier, this installation being characterized in that it comprises a means (10) for measuring the power delivered by the photovoltaic panels to detect a minimum power and means (12) for allowing the supply of at least one electrical appliance by the current coming from the photovoltaic panels and in parallel prohibiting the power supply said electrical apparatus with power from the supplier's supply network to complete the power. 5 Apparatus according to claim 4 characterized in that the electrical apparatus which in their operation heat a volume of water are equipped with a reserve of water with its appropriate resistance to heat the water with the current produced by the panels and the store in reserve.