ITUB20159287A1 - METHOD AND SYSTEM TO OPTIMIZE THE MANAGEMENT OF STORAGE AND TESTING OF A COMPLEX OF ELECTRIC ENERGY ACCUMULATORS AND THE ORGANIZATION OF ELECTRICITY SALES - Google Patents

Description

METHOD AND SYSTEM TO OPTIMIZE THE MANAGEMENT OF STORAGE AND TESTING OF A COMPLEX OF ELECTRICITY ACCUMULATORS AS WELL AS THE ORGANIZATION OF THE SALE OF ELECTRICITY.

Description

The present invention relates to the organization of the production and sale of electrical energy, in particular that produced from renewable energy sources, as well as to the management of the storage and testing of accumulators intended for use in self-contained electrical energy storage systems. produced, for industrial or civil use, as well as those intended for use in the automotive sector.

In particular, the present invention relates to a method and a system for optimizing the aforementioned organization of the sale of electricity and the management of storage of accumulators.

It is known that for some time, with the liberalization of the energy market, producers and retailers who use medium / low energy production plants have multiplied, in most cases from renewable sources.

Consequently, small and medium-sized entrepreneurs have made investments to set up production plants, for example hydroelectric, generally running water, or wind or photovoltaic or biomass and others, then transferring the energy produced to large distributors or, in some cases, directly to end users.

The selling price of electricity is not represented by a fixed value, but varies according to various parameters, such as the moment in which energy is produced and distributed, being higher during the day, when the request is higher and therefore less abundant energy, and lower at night, when the demand decreases due to less industrial activity and energy is available in abundance.

Therefore, for producers, but also for the electricity system as a whole, it would be more advantageous to be able to sell energy in the periods of time in which the price is higher, obtaining greater remuneration and also helping to reduce the peaks in electricity demand. .

These considerations are more valid for those production plants in which, by their nature, it is not possible to manage the resources used in such a way as to optimize the exploitation of the energy source, expanding its economic performance as far as possible. For example, in hydroelectric power plants with an accumulation basin and pumping system, production is stopped during the night and the water used during the day, and appropriately collected in a suitable basin, is re-introduced into the accumulation basin, recovering the hydraulic energy and rationalizing the relationship between production and sale. In other cases, however, this is not possible, in particular with flowing water plants, or those of geothermal or biomass production, in which cases the production is continuous and cannot be stopped, not having primary energy storage systems. .

On another front, again following the liberalization of energy production, and also by virtue of regulations that tend to reduce the causes of emissions of polluting and greenhouse gases due to the production of electricity, self-production of electricity, both for homes and small industries.

It is also known that often, in self-production plants, the moment of energy use does not correspond to the moment of its production, or the quantity of energy needed is greater than that which is supplied at that moment by the system. of generation.

For example, in civilian homes the greatest use of energy is found in the evening hours, when families are gathered in their homes and darkness requires the use of artificial lighting while other energy is required for carrying out different activities. The system, more often photovoltaic, however, provides maximum energy during the day, when the family is usually away from home.

The most used system to overcome these discrepancies between energy production and its use, involves the introduction into the grid of the energy produced in excess, during the day when it is not used or is used to a lesser extent than production, and the subsequent withdrawal from the grid during the evening hours, at the time of need, when the plant does not produce energy.

This "dribbling" of energy between the private production plant and the public distribution network entails a series of disadvantages for the user, well known to the technicians of the sector, among which, for example, the application of tariffs stands out. diversified energy in different time bands, as already mentioned with regard to energy production, and the application of additional costs on the energy withdrawn from the grid, which are obviously not considered with respect to the energy fed into the grid (for example so-called network charges, or excise duties and other additional fees).

To overcome these problems, the implementation of energy storage systems is spreading, which is stowed in suitable accumulator batteries at the time of production and used when necessary, without feeding it into the grid, with the obvious advantages that this entails.

The use of storage systems therefore represents an important and expanding sector in the exploitation of renewable energies. Users of clean energy can take advantage of self-production, thus even managing, in some cases, to completely disconnect from the electricity distribution network.

For this reason, a significant increase is expected in the sector of the production and sale of accumulators for the storage of self-produced electricity, and therefore an increase in the accumulator market.

The increasing diffusion of electric or hybrid traction vehicles also entails an increase in the production of accumulators destined for this purpose, with problems similar to those highlighted above.

On the other hand, due to seasonal and logistical reasons, the retailers of accumulators are forced to prepare large quantities of accumulators in specially prepared warehouses in large buildings, near the sales areas for which they are responsible.

The accumulators, which can reach a total capacity of several tens of megawatt hours or more, remain stored in the warehouses for varying periods of time, but which in any case extend from several days to several weeks, before being sold.

Obviously, the (sometimes very) long stay of the accumulators in the warehouses, unused, can compromise their correct functioning, so much so that it is often necessary to perform a good functioning test, an inspection, before starting them for installation, also to verify any failures caused by the previous transport.

The purpose of the present invention is to optimize both the organization of the sale of the electricity produced, in those cases in which the nature of the energy source does not allow it, and the management of the storage of accumulators collected in the warehouse buildings and intended for systems of industrial and civil electrical energy storage, creating a symbiosis between the producers of electrical energy and the retailers of the accumulators that are in common areas.

Another purpose of the invention is to improve the supply of services to the purchasers of accumulators, to improve the yield of the energy sold by the producers and to make the period in which the latter stay inside the accumulators active for the retailers of accumulators. buildings prepared in the warehouse, all by adopting a conceptually simple method and system that are advantageous from an economic point of view.

The present invention allows its implementation which is certainly advantageous for producers of electricity who use renewable energy sources, in particular for those plants which, by their nature, do not allow a rationalization of production according to the convenience dictated by the sale price, for example. for example, run-of-the-river hydroelectric plants, biomass or geothermal energy production plants and, to a lesser extent, wind energy, as will become clear from the following description.

In fact, the aforementioned purposes are achieved by means of the method and system described in claims 1 and 6, to optimize the organization of the sale of electricity as well as to manage the storage and testing of a set of accumulators, stored in a warehouse, in which it is envisaged to supply the accumulators with energy from a low-cost source of electricity and to connect them to the electricity distribution network, with the interposition of sectioning means, and to provide control means acting on the sectioning means for connect the accumulators to the electricity distribution network or to the low-cost energy source according to the conditions of the sale price on the network and the availability of the electricity in the plant.

The characteristics and advantages of the present invention will be set out in the following description with reference to the attached drawing table, in which:

Figure 1 schematically illustrates an accumulator storage warehouse, and the system in question, organized in such a way as to implement the method object of the invention.

As mentioned in the introduction, the use of accumulators for the exploitation of self-produced electricity is spreading particularly in recent years, and a substantial increase in the use, and therefore in production, of accumulators is expected in the next future, both for civil use, in homes, and for industrial use.

At the same time, the sale of the accumulators takes on importance, which must first be transported from the place of production to the points of sale, and stored there for periods of variable length, depending on the period, to be readily available at the time of installation.

Following the transport and the storage period, it becomes almost inevitable to carry out a test before their installation.

Even the production of electricity, through the use of alternative sources, is gaining importance even at the lowest levels of production, with the setting up of small plants that allow even limited production.

As mentioned in the introduction, the direct supply of energy, especially in plants that do not allow to rationalize the production-sales relationship by interrupting the latter and recovering the exploited energy, as occurs in hydroelectric plants with storage basins and pumping systems, does not always it turns out to be profitable, in the sense that the cost due to production does not always correspond to an adequate sales price. Thus, for example, in run-of-the-river hydroelectric plants, biomass or geothermal plants and other similar ones, production can have a cost that is fully paid off during the day, when the selling price of electricity is generally higher, but that on the other hand, it is not covered at night, when the price falls, even substantially, without any change in production costs.

Obviously, the price variations, which can intervene not only in the approach of the night period with the day one, but also during the holidays with respect to working days, are of different proportions and depend on the country in which the energy producers operate, on the operators of the public and / or private networks and other variables that may be found from time to time.

The production capacity of the plants also changes according to the type of plant, the time of day and also the weather conditions, in some cases.

To a lesser extent, this also applies to a wind power plant, in the sense that it produces electricity continuously, even during times when the selling price is very low, so that production and sale in those hours may not be adequately remunerated. .

It is therefore a question of combining two distinct but complementary needs, namely that of producers / distributors of accumulators, who must optimize the storage and testing of accumulators produced in locations close to the various points of sale, and that of electricity producers, in particular from alternative sources with low cost and low environmental impact, which do not allow to rationalize production as explained above.

The method and the system object of the invention have the purpose of creating a symbiosis between producers / resellers of accumulators and the producers of electricity to optimize the organization of the sale of electricity and the management of the storage and testing of complexes 1 of accumulators 2 for civil, industrial, automotive, etc. The proximity of the two sites allows the exchange of energy as described, also to the mutual advantage of network costs (transport and transformation) that would not be charged.

With reference to the aforementioned drawing table, the number 3 indicates a warehouse in schematic form, consisting for example of a building, shed type, provided for the storage of accumulators 2, also schematized in the figure.

The warehouse 3 will be equipped with systems and equipment necessary for the transport and placement of the accumulators 2 according to the needs and provisions of the regulations of the sector, systems and equipment not illustrated as they are not detected for the purposes of understanding the invention.

The accumulators 2 are connected to each other with suitable series-parallel combinations and according to homogeneous groups, with possible adapter and / or compensation devices, so as to form a complex 1, which is what will result at the ends of the plant.

The accumulator assembly 1 2 will then be connected to a plant or plants for the production of low cost electric energy 6,7,8, preferably of renewable energy, which do not allow the aforementioned rationalization.

In detail, a hydroelectric plant 6, running water, a geothermal plant 7 and a biomass plant 8 have been schematized in Figure 1.

It is understood that the type and number of production plants connected to the accumulator assembly 1 is entirely exemplary, since only the run-of-the-river hydroelectric plant 6 can be provided, or any other combination of plants.

Other sources of renewable energy can also be used, for example biogas, or others, without thereby departing from the scope of the invention, not illustrated for clarity and simplicity of illustration and exposure.

In detail, the accumulator assembly 1 2 is connected to the production plants 6,7,8 by means of sectioning means 11, which will be discussed below.

The hydroelectric plant 6 illustrated, by way of example, is generally equipped with an alternating current generator, more commonly called alternator, and is therefore first connected to a rectifier device 16, downstream of which the others are or can be connected systems, also with the interposition of a rectifier device 161, with the interposition of electrical members suitable for preventing the reverse flow of the current, leveling the voltage produced, etc., all not illustrated as they are not detected with respect to the invention.

The accumulator assembly 1 2 is also connected to an electrical distribution network 10, which can be public or private, with the interposition of other disconnecting means 12, which will be discussed below.

The connection of the plant to the electrical distribution network 10 provides for the interposition of an inverter (the plant operates with direct current while the electrical distribution networks are generally alternating current) and metering means for the energy sold, and possibly withdrawn, to or from the electricity distribution network 10.

The sectioning means 11 and 12 can be constituted by classic disconnectors or preferably by suitable switches, possibly also in solid state, and are controlled by control means 15, adapted to control the sectioning means 11, 12 by means of suitable servo-controls. (not illustrated as of a known type and not detected with the invention).

In detail, the control means 15 comprise processing and memory means, consisting for example of a computer 13 equipped with memory and connected to the internet.

In practice, through the keyboard of the computer 13 it is possible to enter data relating to the sales prices and the costs of producing electricity, schedules and variations in costs, all data which are recorded in the memory. Then, during normal operation, the computer acts on the sectioning means 11, 12 to connect the accumulators 2 to the electrical distribution network 10 or to the renewable energy source 6,7,8 depending on the conditions of the network sale price and the availability of electricity in the plant.

In this way, the accumulators 2 are connected to a source of electric energy 6,7,8 in order to charge them when the price of electricity is lower, disconnecting them from the electricity distribution network 10 to which they are then connected when the selling price of electricity is higher.

If the energy produced when the sale price is lower exceeds the storage capacity of complex 1, the excess energy produced can still be fed into the grid, in the case of wind power 7 or photovoltaic 8, while with the hydroelectric plant 6 it is possible to interrupt the flow of water from the basin to the production plant, conserving the hydraulic energy, or if it is not possible due to the filling of the basin, then also in this case the energy produced in excess is however fed into the network.

The different functional configuration of the system is defined by the computer 13, setting the most favorable condition.

The following table exemplifies some possible operating situations of the system.

period production price link condition sales / to the operating network cost of

production

day / weekday high / high normal activated system and complex 1 deliver energy to the network night / holiday low / low normal deactivated system recharging complex 1 night / holiday low / low in excess activated system recharging complex 1 and supplies energy to the network Previously yes always talked about renewable energy generation plants, this representing the case of greater convenience, in particular the hydroelectric plant, but the system described here could be used, even with non-renewable production plants, or even by drawing electricity from the network, when the selling price is lower, to accumulate it in accumulators 2, and then re-inserting it into the network when the selling price is higher.

In this case, the low-cost source of electrical energy is constituted by the electrical distribution network 10 itself, at the moments of the lowest selling price.

The current flow between the accumulator complex 1 and the production plants and the electrical distribution network 10 is in any case measured by metering means 18, to provide for the subsequent billing of the energy sold, on the one hand, and purchased, on the other.

It is evident that the method and the system proposed by the present invention are able to achieve the purposes indicated in the introduction.

In particular, a symbiosis is created between the producers of accumulators and the producers of electricity, which makes it possible to optimize the organization of the sale of electricity and the management of storage and testing of the complexes 1 of accumulators 2 for civil, industrial, automotive, etc. electrical energy storage systems.

Furthermore, the method and the system of the invention allow to improve the supply of services to the purchasers of the accumulators, to improve the yield of the energy sold by the producers and to make active for the retailers of accumulators the period in which the latter are stationed at inside the buildings set up in the warehouse, all in a simple and advantageous way from an economic point of view, as well as contributing to the lowering of electricity demand peaks to the advantage of the electricity grid in general.

The types of accumulators that can allow the implementation of the present invention are the most diverse, from those used for the accumulation of self-produced energy in civil and industrial plants, to those used on electric transport vehicles.

The present invention allows its implementation which is certainly advantageous in particular for producers of electrical energy who use renewable energy sources, preferably with hydroelectric plants.

The systems and equipment mentioned and described constitute a system defined only schematically, in the sense that other known equipment may be provided or necessary for the correct operation of the systems, without this compromising the scope of the invention, as highlighted above.

It is also understood that what above has been described purely by way of non-limiting example. Therefore, possible modifications and variants of the invention are considered to fall within the protective scope accorded to the present technical solution, as described above and claimed hereinafter.

Claims (10)

Claims 1. Method for optimizing the organization of the sale of electricity as well as for managing the storage and testing of a set (1) of accumulators (2) stored in a warehouse (3) which contains said set (1) of accumulators ( 2), characterized by providing for powering said accumulators (2) with energy from a low-cost source of electricity (6,7,8,10) and to connect them to the electricity distribution network (10), to provide control means (15) suitable for determining the connection of said accumulators (2) to the electricity distribution network (10) or to the low-cost source of electricity (6,7,8,10) depending on the conditions of the network sales price and overall electricity availability (1). 2. Method according to claim 1, which provides for the realization of said control means (15) by means of processing and memory (13), able to control, by means of suitable servo-controls, sectioning means (11,12) which detach or connect said accumulator complex (1) (2) respectively to and from the electricity source and to and from the electricity distribution network (10). 3. Method according to claim 1 or 2, in which said control means (15) connect said accumulators (2) to a low-cost source of electrical energy (6,7,8,10) to effect the charging thereof in the moments in which the price of electricity is lower, and connect said accumulators (2) to the electricity distribution network (10) when the selling price of electricity is higher. Method according to one of claims 1 to 3, wherein said low-cost electricity source (6,7,8) is constituted by a renewable energy source intended to operate continuously, being able to be constituted by a hydroelectric plant (6) running water and / or from a geothermal plant (7) and / or from a biomass plant (8). Method according to one of claims 1 to 4, in which accumulators (2) provided for civil and industrial storage systems of electric energy, or for use in the automotive industry for electric traction, are used. Method according to one of claims 1 to 5, in which said low-cost source of electrical energy (10) is constituted by the same electrical distribution network at times when the selling price of electrical energy is lower. 7. System for optimizing the organization of the sale of electricity as well as for the management of the storage and testing of a complex (1) of accumulators (2) stored in a warehouse (3), characterized by the fact that said accumulators (2) are connected to a low-cost source of electricity (6,7,8) and connected to the electricity distribution network (10), with the interposition of sectioning means (11,12) and with control means (15) acting on said sectioning means (11,12) to connect the accumulators (2) to the electricity distribution network (10) or to the low-cost renewable energy source (6,7,8) according to the conditions of the network sale price and the availability of electricity as a whole (1). 8. System according to claim 7, in which said control means (15) are constituted by processing and memory means, able to control, by means of suitable servo-controls, the aforementioned sectioning means (11,12) to connect said accumulators (2 ) to a low-cost source of electricity (6,7,8,10), to charge them when the price of electricity is lower, and to connect them to the electricity distribution network (10) in the when the selling price of electricity is highest. System according to one of claims 7 or 8, wherein said low-cost source of electricity (6,7,8) is constituted by a renewable energy source intended to operate continuously, consisting of a hydroelectric plant (6) flowing water, and / or from a geothermal plant (7) and / or from a biomass plant (8), and said accumulators (2) are intended for civil and industrial storage systems of electrical energy and for automotive electric traction . System according to one of claims 7 to 9, wherein said low-cost source of electrical energy (10) is constituted by the same electrical distribution network at times when the selling price of electrical energy is lower.