PL229822B1 - Method for processing resources of renewable energy for the purposes of supplying electric isolated networks, where obtained renewable energy is stored, the point of the maximum output of the renewable energy sources is monitored and its obtained quantity is examined, and the system of the energy resources processing for the purposes of the isolated electric networks where presence of renewable energy is decoded, it is stored, point of the maximum output of renewable sources of energy are monitored and its obtained quantity is tested, and the method of controlling the energy resources processing system - Google Patents

Abstract

In the renewable energy processing method, variable priorities are given for the processing of the obtained renewable energy resources, the renewable energy resources are divided according to variable dependencies into a variable number of parts, each of which is separately processed. Time intervals are defined in which separate electrical networks are powered. In the energy resource processing system, the outputs of renewable energy sources are connected with the energy summing-dividing system, and its outputs are connected with the receiving systems. The outputs of the renewable energy sources are connected to the renewable energy appearance detector and the control outputs of the renewable energy appearance detector are connected to the control and control power supply system. A clock is connected to the control and control power supply. In the method of controlling the processing circuit, control information is received and responded to, and the functions of the control element are changed simultaneously.

Description

Description of the invention

The subject of the invention is a method of processing energy resources from renewable photovoltaic sources, in which the obtained energy is stored, the point of maximum efficiency of the sources is monitored, the amount obtained is tested, at least a few receivers powered by direct current are used, and a method of processing renewable energy resources from renewable photovoltaic sources , in which the obtained energy is stored, the point of maximum efficiency of the sources is monitored, its obtained amount is tested, at least several receivers powered by direct current with different powers are used, and a renewable energy resource processing system, in which the presence of renewable energy is decoded, is stored it is tracked, the point of maximum efficiency of renewable energy sources is tracked and its obtained amount is examined and in which several heaters are connected to the same system of photovoltaic cells through a system of switches, the operation of the control system is also powered from other source and in which the receivers connected to the AC network are turned on.

The solutions already described in the publications "Hybrid generation systems and microgrids as a way to develop distributed generation" Prof. Dr. hab.inż Józef Paska 2013, "Energy quality in distributed generation systems" Tomasz Sikorski, Grzegorz Kosobudzki 2011, "Design and implementation of a hybrid regenerative power system combining grid-tie and uninterruptible power supply functions "HCChiang, TTMa, YHCheng, JMChang, WNChang 2009," Modeling, control and simulation of a PV / FC / UC based hybrid power generation system for stand-alone applications ”M.Uzonoglu, OCOnar, MSAIam Renewable Energy 34 (2009) 509-520 show how to increase the possibilities of using renewable energy sources using hybrids. In these and other solutions, it is possible to obtain renewable energy using such examples of renewable energy as wind or solar energy. Some of these solutions are constantly powered by batteries, and when renewable energy appears, the batteries are recharged, utility water is heated with the obtained electricity, rooms are heated, electricity is generated to power electrical devices or it is fed into the main network. When obtaining renewable energy, the point of maximum efficiency of renewable sources is monitored and based on this operating point, the optimal load is sought to obtain the largest amount of energy per unit of time. For this purpose, a PWM change is implemented. Some of the differently constructed devices process renewable energy without storing it in batteries, still others are equipped with batteries, which are usually recharged, and the energy stored in them is used for processing to the form expected by the end user at a different date. The user may consider such systems as a primary or backup power source. Typically, in such systems, the batteries constitute a buffer connected between the renewable energy harvesting system and the renewable energy or battery energy converting system to a form required by the end user. Some of these devices only provide supervision and direct control by the operator, others enable their inclusion in the system, their remote control and control in a wired or wireless manner.

Still other devices test the efficiency of photovoltaic cells by measuring solar radiation with the use of additional light converters, and the loading of the cells can be done by gradual load change, which is done by connecting or disconnecting resistive loads of different powers. As a result of switching receivers, a system of connected receivers with the power closest to the efficiency of photovoltaic cells is obtained.

In the method of processing renewable energy according to the invention, also in the absence of renewable energy, signals to activate the clock (12) are received from the system of photovoltaic cells (3) and it is checked whether to generate signals controlling the switching of the power supply from the AC grid (9) to the AC load (8) or / and control signals are generated for switching the AC mains (9) to the AC load (8). Power switching control signals are generated, as a result of which the DCAC converter (5) is powered from the battery (1) and the power switching control signals are generated from the DCAC converter (5) to the AC load (8) and the DCAC converter activation signals are generated. (5) supplying AC load (8). In the absence of renewable energy, user intervention signals and / or intervention signals are received from the remote monitoring system and the power supply is switched from the AC grid (9) to the AC load (8) or from the DCAC converter (5) to the AC load (8) or simultaneously from the AC mains (9) and from the DCAC converter (5) to the AC load (8).

In the method of processing renewable energy according to the invention, the signals of the amount of energy obtained are examined at intervals and when the photovoltaic cell system (3) is loaded

With a non-optimal power, receivers are selected, the total power of which is closer to the point of maximum efficiency of the photovoltaic cell system, the signals controlling the switching of power from photovoltaic cells to DC receivers are generated, as a result of which only such selected receivers are connected to the photovoltaic cell system. Consumers such as the DCAC processing unit (5) and / or the battery charging system (6) and / or the heater (7) are selected, which are given higher priority for connection to the photovoltaic cell system. When the photovoltaic cells system (3) is loaded with a non-optimal power, the power consumed by at least one of several receivers connected to the photovoltaic cell system (3), such as the DCAC processing system (5) and / or the battery charging system (6), changes in such a way that the total load is close to the point of maximum efficiency of the photovoltaic cell system. Depending on the signals of the presence of the AC power grid (9) and / or the charging of the batteries (1) and / or the efficiency of the photovoltaic cell system (3), a combination of receivers such as the DCAC energy conversion system (5) and / or the battery charging system (6) is selected or / and heaters (7), power signals are switched from (wind turbine (2) or photovoltaic cell system (3) or batteries (1)) or (wind turbine (2) and / or photovoltaic cell system (3) and / or batteries (1)) to the selected combination of receivers. Also in the absence of renewable energy, clock activity signals (12) are received from the photovoltaic cell system (3) and it is checked whether to generate and / or generate control signals for switching the power supply from the AC grid (9) to the AC load (8).

In the renewable energy resource processing circuit according to the invention, a clock control output is connected to the input activating the energy resource processing circuit. The outputs of renewable energy sources such as a wind turbine (2) and / or a photovoltaic cell system (3) are connected to the input of the renewable energy appearance detector (11), and the control outputs of the renewable energy appearance detector are connected to the input to activate the operation.

The advantage of this method of processing is to ensure the highest priority of using renewable sources, both in on- and off-grid systems, to supply power to receivers and, at the same time, to reduce AC power consumption from the grid, to properly care for the state of charge of the batteries while at the same time ensuring guaranteed power supply at the consumer at least in the allocated intervals. temporal. All this can be done both in the absence of grid energy and renewable energy by carrying out tasks at programmed time intervals, at the request of the user or a supervisory system, supplying the receivers with the highest priority, depending on access to renewable energy or the battery charge level.

The advantage of the second processing method is to reduce the cost of converters and reduce dimensions, increase reliability and in some cases reduce losses while increasing or maintaining processing efficiency and increasing or maintaining the tracking of the maximum efficiency of renewable sources.

In the course of work in order to obtain the maximum available amount of renewable energy and its optimal transformation, taking into account the randomly changing conditions of its acquisition and the randomly changing needs of consumers, priorities are assigned in a variable manner, such as reducing the costs of energy consumed from the main grid, ensuring the highest efficiency of obtaining energy, ensuring continuity of supply. The division of the obtained renewable energy into a variable number of parts, each of which is processed in a different way, enables the optimal use of all available renewable energy. This is done as a result of energy redirection only to connected receivers with variable priority priorities, which optimizes the loading of renewable sources in the full scope of their operation and ensures the implementation of variable user preferences. Indirectly, it also makes it possible to increase the efficiency of energy conversion.

Connecting the outputs of renewable energy sources with a switching system and its outputs with receiving systems enables the redirection of the amount of energy tailored to the needs of receivers and the current optimal efficiency of sources from any sources to any receivers by dividing the energy obtained into parts tailored to the needs, and when energy is obtained at the same time from several renewable sources, it is redirected from the source with the highest efficiency to the receiver with the highest priority, and when this energy is missing, the shortage of energy is taken from the second source, and its surplus energy is transferred successively to the receivers with lower priorities. An additional effect is to ensure optimal loading of energy sources, which optimizes their operating point, increasing the efficiency of obtaining renewable energy, this reduces energy conversion losses, enables the collection and use of renewable energy from both a source with temporary residual efficiency.

PL 229 822 B1 (even below 1% of the rated power) and from the source operating at the operating point close to 100% efficiency, which in the long term increases the return on investment very significantly.

Combining the outputs of renewable energy sources with a renewable energy appearance detector, and the control outputs of the renewable energy appearance detector with the power supply, control and control system allows the system to wake up from standby and start obtaining renewable energy only when necessary. In this way, energy losses for supporting the operation of a non-productive device are reduced, ensuring its activity when the device is supposed to work. The combination of the clock and the signals of user intervention and the signal from the remote supervisory system with the power supply, control and control system enables the power supply to the separated network and the implementation of the basic goals of the installation in the time intervals important for the user, when renewable energy is not obtained and the main power supply network has failed, which contributes to for more effective and long-term use of energy stored in the batteries. Both the collection and conversion of energy are thus optimized, making the system run reliably and predictably.

The invention will be explained in more detail in an exemplary description of the operation of the device - not limiting its scope of application - for acquiring and processing renewable energy, in which energy sources such as batteries (1), wind turbine (2), photovoltaic cell system (3) are connected to the system switching (4) and the power, control and command system (13). Additionally, a wind turbine (2) and a system of photovoltaic cells (3) are also connected to the detector of the appearance of renewable energy (11). The outputs of the switching circuit (4) are connected to the inputs of energy receivers such as the DCAC converter with a network switch (5), the battery charging circuit (6), and heaters (7). The AC power supply network (9) is connected to the second input of the DCAC processing system with the network switch (5) and the mains failure detector (10) and the input of the power supply, control and control system (13), and the DCAC processing output with the network switch (5) connects to the AC load (8). The control outputs of the mains failure detector (10), the renewable energy appearance detector (11) and the clock (12) are connected to the control inputs of the power supply, control and control system (13). The clock bi-directional communication bus (12) connects to the control and command circuit (13), the control outputs of the control and command circuit (13) connects to the summation-divider (4), DCAC processing circuit and network switch (5), charging circuit the batteries (6). The output of the battery charger (6) connects to the batteries (1).

While the AC power grid (9) is present and renewable energy sources such as a wind turbine (2) and a photovoltaic cell system (3) do not produce renewable energy, the control and control power supply (13) keeps the device on standby, i.e. , in which the energy consumption from the batteries (1) is negligible. Only the systems of the network failure detector (10), the renewable energy appearance detector (11) and the clock (12) are active. In this state, the AC load (8) is supplied from the AC supply network (9) through the DCAC converter with the network switch (5).

The appearance of renewable energy in one of the sources such as a wind turbine (2) or a photovoltaic cell system (3) in an amount that exceeds the set level of this renewable energy is decoded by the renewable energy appearance detector (11), which by its output activates the power supply to the system power supply, control and steering (13). The power supply, control and control system (13) becomes active and activates the power supply of all systems, drawing energy from the batteries (1). After turning on the power, the power supply, control and control system (13) decodes the state of its inputs and learns the reason for turning on the power as an inclusion resulting from the appearance of energy from the wind turbine (2) or, respectively, of the photovoltaic cell system (3). The power supply, control and control system (13) activates its output connected to the summation-divider (4) and through this system it redirects these small doses of energy from the energy source (2) or (3) to the battery charging system (6), and at the same time, the system output connected to the battery charging system (6) activates this system and starts charging the batteries (1). The power supply, control and control system (13) uses inputs connected to the wind turbine (2) and the photovoltaic cell system (3) to test the amount of renewable energy obtained and by changing the operating parameters of the battery charging system (6), it charges the optimally active source of this energy. The power supply, control and command system (13) monitors their state of charge by means of inputs connected to the batteries (1).

When the batteries (1) are not discharged, and during the optimal loading of the active energy source (2) or (3), the power supply, control and control system (13) determines that the amount of energy transferred to the batteries (1) exceeds the rated charging current value, then this circuit interrupts the charging of the batteries (1) and activates the DCAC processing circuit and the network switch (5)

It transmits renewable energy to the input of the DCAC processing circuit (5) through the circuit of switches (4). The DCAC conversion circuit and the network switch (5) after the start of operation synchronize to the AC mains (9), and after synchronization through the mains switch in (5) it disconnects the AC mains (9) and with processed renewable energy it supplies the AC load (8). ). After energizing the AC load (8), the power supply, control and control system (13) examines the load point of the connected renewable energy source of the wind turbine (2) or the photovoltaic cell system (3). When the connected source (2) or (3) is overloaded, the control and control power supply system (13) loads them more optimally by redirecting additional energy from the batteries (1) to the input of the DCAC processing system (5) through the summation-divider (4).

When the amount of energy from renewable energy sources (2) or (3) increases beyond the needs of the AC load (8), the power supply, control and command circuit (13) interrupts the redirection of additional energy from the batteries (1) to the input of the DCAC processing circuit and the network switch (5). ) and by changing the operating parameters of the battery charging system (6), it loads the optimally active source of this energy (2) or (3) and charges the batteries (1). When the amount of renewable energy obtained from sources (2) or (3) exceeds the need to supply the AC load (8) and charge the batteries (1) of the power, control and control system (13), it decodes this state and redirects the surplus energy through the system of switches (4) from the source (2) or (3) to the heaters (7).

When the batteries (1) are discharged, and during the optimal loading of the active energy source (2) or (3), the power supply, control and control system (13) determines that the amount of energy transferred to the batteries (1) is too large, the excess energy through the summation and divider system (4) it will transfer to the heaters (7) keeping the process of charging the batteries (1) as superior. The power supply, control and control system (13), by examining the amount of energy transferred to the batteries (1) and heaters (7), while maintaining the optimal operating point of the sources (2) or (3), calculates whether the obtained energy is sufficient to supply the AC load (8) . If the result of these calculations is positive, the power supply, control and control system (13) will redirect energy from energy sources (2) or (3) to the input of the DCAC processing system and the network switch (5) through the summation-divider (4), after synchronization, it will disconnect the AC network (9) from the AC load (8) and redirect the acquired energy to the AC load (8). Only the surplus of renewable energy obtained will recharge the batteries (1). When the amount of renewable energy obtained from sources (2) or (3) exceeds the needs of the DCAC processing system and the network switch (5) and battery charging (1) of the power, control and control system (13) decodes this state and through the switching circuit (4) redirects excess energy to the heaters (7).

The disappearance of renewable energy on both energy sources, such as a wind turbine or a photovoltaic cell system (3) will load the batteries (1) and after a set time necessary to synchronize the DCAC processing system and the network switch (5) to the AC power grid (9), the load will no longer be supplied AC (8) from the DCAC processing unit in (5), feeding this network from the AC mains (9) and switching the power supply, control and control system (13) to standby.

If there is renewable energy on each of the sources such as a wind turbine (2) and a system of photovoltaic cells (3), the obtained amounts of this energy will be added by the switching system (4) and the power supply, control and control system (13) will transfer and process the resulting energy in the system battery charging (6), DCAC processing system in (5) and heaters (7).

If, in the absence of renewable energy, the power supply, control and command system (13) is activated due to the intervention of the user or an external remote master system, it will be powered by the batteries (1) and will remain active until the user or the remote master system does not allow the power supply from the batteries to be turned off. (1). If, during the active state of the power supply, control and control system (13), it receives a user's command or an external command to activate the AC load (8), it will execute this command until this command is changed or until it detects the state of discharging the batteries (1). If, during the active state, renewable energy appears on one or both of the sources, the power supply, control and control system (13) will start to acquire and process it as described above. The disappearance of this renewable energy will not cause the power supply, control and steering system (13) to go into the standby mode, maintaining the previously performed tasks. If, during the production of renewable energy, the user or the remote master system gives the power, control and control system (13) command to disable the active state, this command will be executed after the disappearance of renewable energy on the wind turbine (2) and the photovoltaic cell system (3). During the conversion of renewable energy, the user or the remote supervisory system may stop redirecting the renewable energy to the AC load (8). Then

This energy will be redirected only to charge the batteries (1) and heaters (7), and the AC load (8) will be supplied from the AC mains (9).

In the event of a lack of sufficient renewable energy resources and AC power failure (9), the clock circuit (12), after measuring the pre-programmed activation time, activates the control and control power supply system (13) with its control signal, which goes into the active state and is powered by batteries (1). After activation, the control and steering power supply system (13) examines the state of control inputs and determines the cause of activation as activation of the clock (1) and examines the state of the AC network (9). If the control and command power supply system (13) detects a failure of the AC network (9), it redirects the battery energy (1 through the switching circuit (4) to the DCAC converter (5), disconnects the AC supply network (9) and supplies the AC load (8) to the processed battery energy (1) in the DCAC conversion system (5). If, after this activation, the control and control power supply system (13) decodes the presence of renewable energy from wind turbine sources (2) or the photovoltaic cells system (3), it redirects this energy to the conversion system DCAC and mains switch (5), battery charging circuit (6), heaters (7) as previously described.If the renewable energy fades, the AC load (8) will be further supplied with energy from the DCAC converter and mains switch (5) fed from the batteries (1). If the AC load (8) is supplied with energy from the DCAC processing system (5) powered from the batteries (1), and the power supply, control and control system (13) detects the appearance of AC mains (9) this will synchronize the DCAC converter and mains switch (5) to the AC mains (9), connect the AC load (8) to the AC mains (9). If it does not decode the possibility of using renewable energy from sources, the wind turbine (2) or the system of photovoltaic cells (3), the power supply, control and control system (13) will go into standby mode. If he decodes the possibility of consuming renewable energy, he will process it in the manner described previously.

If, while supplying the AC load (8) from the DCAC processing system and the network switch (5) powered from the batteries (1), the clock (12) measures the shutdown time, the power supply, control and control system (13) will interrupt the AC load (8) the DCAC processing unit and the mains switch (5) powered by the batteries (1) and the power, control and control unit (13) will switch to standby. In standby mode, the AC load (8) is connected to the AC grid (9), so the appearance of energy in the AC grid (9) will immediately power the AC load (8).

If, while supplying the AC load (8) from the DCAC processing unit and the network switch (5) powered from renewable energy sources (2) or (3), the timer (12) measures the shutdown time, the power supply, control and control circuit (13) will continue feeding the AC load (8) with renewable energy from sources (2) and / or (3). Reducing the amount of renewable energy obtained will connect the AC load (8) to the AC power grid (9) and continue charging the batteries (1), and the complete loss of renewable energy will cause the power supply, control and control system (13) to switch to standby.

Claims (10)

1. The method of processing energy resources from photovoltaic renewable sources, in which the obtained energy is stored, the point of maximum efficiency of the sources is monitored, its amount is tested, at least a few receivers powered by direct current are used, characterized by the fact that also in the absence of renewable energy with of the photovoltaic cell system (3), signals to activate the clock (12) are received and it is checked whether to generate control signals for switching the power supply from the AC network (9) to the AC load (8) or / and to generate control signals for switching the power supply from the AC network (9) to AC load (8). 2. A method for processing energy resources according to claim The method of claim 1, characterized in that power switching control signals are generated, whereby the battery (1) powers the DCAC converter (5) and produces power switching control signals from the DCAC converter (5) to the AC load (8) and generates activation signals of the DCAC converter (5) supply the AC load (8). 3. A method for processing energy resources according to claim The method of claim 1, characterized in that, in the absence of renewable energy, user intervention signals and / or intervention signals are received from the remote supervisory system and the power is switched from the AC grid (9) to the AC load (8) or from the DCAC processing circuit (5) to the load. AC (8) or simultaneously from the AC network (9) and from the DCAC converter (5) to the AC load (8). PL 229 822 B1 4. The method of processing renewable energy resources from renewable photovoltaic sources, in which the obtained energy is stored, the point of maximum efficiency of the sources is monitored, the amount obtained is tested, at least several receivers powered by direct current with different powers are used, characterized by the fact that at intervals, signals proving the amount of energy obtained are examined and when the photovoltaic cell system (3) is loaded with non-optimal power, receivers are selected whose total power is closer to the point of maximum efficiency of the photovoltaic cell system, signals are generated that control the switching of power supply from photovoltaic cells to DC receivers, as a result, only such selected receivers are connected to the photovoltaic cell system. 5. A method for processing energy resources according to claim 4. A method as claimed in claim 4, characterized in that the receivers such as the DCAC processing circuit (5) and / or the battery charging circuit (6) and / or the heater (7) are selected, which are given higher priority for connection to the photovoltaic cell circuit. 6. A method for processing an energy resource according to claim 4. The method of claim 4, characterized in that when the photovoltaic cells system (3) is loaded with a non-optimal power, the power consumed by at least one of several receivers connected to the photovoltaic cells (3) system, such as the DCAC processing system (5) or / and the battery charging system ( 6) in such a way that a total load of a value close to the point of maximum efficiency of the PV array is obtained. 7. A method for processing an energy resource according to claim 4. The method according to claim 4, characterized in that depending on the signals of the presence of the AC power grid (9) and / or the charging of the batteries (1) and / or the efficiency of the photovoltaic cell system (3), a combination of receivers such as the DCAC energy conversion system (5) and / or the system is selected charging of batteries (6) and / or heaters (7), power signals are switched from (wind turbine (2) or photovoltaic cell system (3) or batteries (1)) or (wind turbine (2) and / or from solar cell system photovoltaic (3) and / or accumulators (1)) to the selected combination of receivers. 8. A method for processing an energy resource according to claim 4. The method according to claim 4, characterized in that also in the absence of renewable energy, signals of the clock activity (12) are received from the photovoltaic cell system (3) and it is checked whether to generate and / or generate control signals for switching the power supply from the AC grid (9) to the AC load ( 8). 9. Renewable energy resource processing system, in which the presence of renewable energy is decoded, stored, the point of maximum efficiency of renewable energy sources is tracked and the amount obtained is tested and in which several heaters are connected to the same photovoltaic cell system through a system of switches, the operation of the control system is also supplied from another source and in which the receivers connected to the AC network are switched on, characterized in that the clock control output is connected to the input activating the operation of the energy resource processing system. An energy resource processing system as claimed in claim 10; The method of claim 9, characterized in that the outputs of renewable energy sources such as a wind turbine (2) and / or a photovoltaic cell system (3) are connected to the input of the renewable energy appearance detector (11), and the control outputs of the renewable energy appearance detector are connected to input that activates the work.