WO2020181342A1

WO2020181342A1 - Optimized junction box

Info

Publication number: WO2020181342A1
Application number: PCT/BR2019/000010
Authority: WO
Inventors: Cleriston de Morais LEAL
Original assignee: Maré Brasil Energia E Equipamentos Ltda
Priority date: 2019-03-14
Filing date: 2019-03-14
Publication date: 2020-09-17

Abstract

The optimized junction box according to the present invention is a junction box (100) including a smart electronic circuit that makes it possible to improve the output efficiency of the circuit using firmware arranged together with the microcontroller (20), which makes it possible to maintain a constant voltage, such as to manage and monitor the voltage in all of the switches, and together with the capacitor array, varying the voltage between serial and parallel, resulting in continuous management of the dissipated electrical current in order to prevent a drop in electrical current. This electronic circuit is able to increase the output efficiency of the circuit, controlling the output voltage, subject to voltage transients, minimizing surges using a system to increase voltage without decreasing current using an electronic arrangement, actuated by time or load, increasing the efficiency of the assembly.

Description

OPTIMIZED JUNCTION BOX

FIELD OF THE INVENTION

[01] The present invention describes an optimized junction box. More specifically it comprises a junction box that presents an intelligent electronic circuit that makes possible to increase the efficiency of the circuit output through a firmware arranged next to the microcontroller, that allows to maintain the voltage constant, in order to manage and monitor the voltage in the set of switches. and next to the capacitor arrangement, the voltage varying in series and in parallel, resulting in a constant management of the dissipated electric current in order to avoid a decrease in electric current.

[02] This new constructivity allows its application with several electronic devices that need a voltage control and management, being preferentially applied next to the photovoltaic panels, in order to increase the output voltage of the modules, subject to voltage transients, minimizing surges through a system of voltage increase and no decrease of electric current, by means of an electronic arrangement, activated over time, providing an increase in efficiency.

BACKGROUND OF THE INVENTION

[03] Photovoltaic panels are structures that have a set of photovoltaic cells made of semiconductor materials interconnected in series (strings) protected by a special tempered glass coated with an anti-reflective substance, called a photovoltaic cell that absorbs solar energy. The moment the particles of sunlight, the photons, collide with the atoms of the photovoltaic cells, they cause the displacement of the electrons, generating electricity.

[04] Depending on the need, several plates can be arranged and connected in parallel. Large systems using series of batteries can reasonably supply different (and consistent) energy needs.

[05] At the rear of each photovoltaic panel, two conductors are arranged from a junction box, said cables used to communicate the photovoltaic solar panels, which within a set, form a series of photovoltaic panels. This set of photovoltaic panels is then connected, through direct current cables, to the solar inverter, which is responsible for converting the generated energy into energy that can be used in homes or businesses.

[06] _{> In} a junction box, the photovoltaic cells are electrically interconnected, protecting the panel against reverse current (which can occur at night or in shadows) through diodes and facilitating the exit of the conducting cables of the solar panels. In this way, it is avoided, for example, that the plates during the night work in reverse, consuming charge and discharging the energy stored in batteries, or due to a shading during the day “consume” the energy of other plates.

[07] Conventionally, junction boxes, also called Siring Boxes, serve to accommodate all connections of direct current circuits coming from the photovoltaic panel, through protection devices, such as disconnect switches, fuses, circuit breakers and surge protection (DPSs), producing an output (DC) that connects to the DC input of the power inverter.

[08] In systems with more than one photovoltaic module, observed loss problems by association, known as mismaíchfoss, an effect studied by several authors (Gonzáles, CC, 1986. Photovoltaic Array Loss Mechanisms. Sol Celis, 18, 373-382; Chamberlin, CE, et al, 1995, Effectsofmismatchlosses in photovoltaicarrays. Solar Energy, 54, 165-171). This effect corresponds to the decrease in the total power of the system when compared to the sum of the individual powers of all associated modules due to the electrical differences between the modules and possible shading. The possibility of degradation of the modules that make up the installation can significantly increase, depending on the type of existing connections, with the shading of only one cell of a module, causing the system current to decrease and, consequently, its power. In extreme cases, all the power generated by the system can be lost by the simple fact of having a shaded or defective cell.

[09] To avoid problems arising from these unwanted situations, but which occur throughout the life of the system, protection devices must be added, generally dodos, which are placed at strategic points of the installation (Hecktheuer, LA, 2001, Analysis of Associations of Photovoltaic Modules, Doctoral Thesis, PROMEC / UFRGS, Porto Alegre, Brazil).

[010] The panel with the lowest voltage can behave as a load for the other panels. In this way, part or all of the current generated by the panels with the highest voltage will flow through the lower voltage panel, causing heating in the latter and loss of system power. The use of blocking diodes connected in series with the modules of each panel prevents the appearance of reverse currents. In photovoltaic systems that have combinations of modules in series and parallel, the protection of the generators is achieved using, simultaneously, bypass and blocking diodes.

[011] In research carried out with the state of the art, we identified several documents that describe solutions for junction boxes, where we can highlight the following documents: {012] The document BR112014013284 describes a semiconductor substrate for a photovoltaic energy module that includes one or more bypass diodes formed sntegralmeníe in the semiconductor substrate, each bypass diode corresponding to one or more photovoltaic cells and metallized zones being electrically and thermally coupled to the bypass diodes. The substrate allows photovoltaic cells to be located close to each other and have low thermal resistance. The methods of manufacturing the substrate and module are provided.

[013] The document CN 107565800 describes a photovoltaic energy optimizer that comprises an energy optimization module, a bypass module and a control module. The bypass module is connected to the input end of the power optimization module, the output end of the power optimization module and the control module. The control module is connected to the energy optimization module. The control module is used to control the bypass module to be performed when the failure of the energy optimization module is detected so that the failed energy optimization module is activated and a photovoltaic cell component is connected directly in series with other cell packages of the photovoltaic power generation system and accessed to the inverter. Then, the energy generated by the photovoltaic cell component can be effectively generated so that energy waste caused by the failure of the energy optimization module can be avoided.

[014J Document CIM 107248843 describes a method of controlling photovoltaic generation, control equipment and a photovoltaic generation system. When shielding occurs or the component is faulty, an optimizer in the photovoltaic generation system quickly adjusts an output voltage setpoint and the generation capacity of the system cannot be influenced, Q method is applied to the photovoltaic generation system; the method comprises the following steps: the control equipment periodically sends an instruction to update the output voltage reference value to the optimizer of each sirin of the photovoltaic group; the photovoltaic group chain optimizer receives the instruction to update the output voltage setpoint and updates the output voltage setpoint according to the output voltage setpoint.

[015] G WO2018149375 describes a device for supplying power, voltage and / or current from a combination of photovoltaic modules. And one aspect, the system has a central energy optimizer, located between a group of distributed energy optimizers and a solar inverter. Each distributed energy optimizer can be connected to the DC output of one of the photovoltaic modules and can be used to regulate the photovoltaic module's power output. The combined DC voltages of the distributed energy optimizers can be supplied to the input of the central energy optimizer. [016] The documents identified in the state of the art present energy optimizers that aim to convert the voltage DC / DC or DC / DC, so that these devices are connected to each solar module, however these documents present complex systems equipped with different electronic components that do not solve the inconvenience of shading on the plates in order to generate a loss in efficiency and a decrease in electric current.

[017] Thus, in order to contribute to the stabilization, increase and efficiency of the photovoltaic modules, an electronic arrangement was developed with an intelligent electronic circuit that makes it possible to increase the output efficiency of the photovoltaic panel circuit through a firmware, arranged next to the mscrocontroller, which allows to keep the voltage constant, in order to manage and monitor the voltage in the set of switches and next to the arrangement of eapacitors, varying the voltage now in series and now in parallel, resulting in a constant management of the dissipated electric current the plates in order to avoid a decrease in electrical current. This electronic circuit is capable of increasing the output efficiency of the photovoltaic modules circuit, controlling the output voltage of the modules, subject to voltage transients, minimizing surges through a voltage rise system and not decreasing current through a electronic arrangement, triggered over time, providing increase and efficiency of the set.

SUMMARY OF THE INVENTION

[018] The characteristic of the present invention is an optimized junction box that provides an intelligent electronic circuit that makes it possible to increase the voltage output efficiency, in order to allow its application with various equipment, preferably applied to photovoltaic panels.

[019] It is characteristic of the present invention an optimized junction box that provides a circuit equipped with a microcontroller that has a firmware that allows to alternately manage, monitor and control the voltage, either in series or in parallel.

[02OJ It is characteristic of the present invention an optimized junction box that provides a voltage management and monitoring system in the set of switches and next to the capacitor arrangement, varying the voltage now in series and now in parallel, resulting in a constant management of electrical current dissipated by the plates in order to avoid a decrease in electrical current.

[021] It is characteristic of the present invention that an optimized junction box that provides electronic circuit is able to increase the efficiency of the circuit output of the photovoltaic modules, controlling the output voltage of the modules, subject to voltage transients, minimizing surges through a system for raising voltages and not decreasing current through an electronic arrangement, triggered over time, providing increase and efficiency of the set,

[022] It is characteristic of the present invention an optimized junction box that provides a second constructive form that uses electronic or eietromechanical components, without using the microcontroller and firmware.

[023] It is characteristic of the present invention an optimized junction box that provides a third constructive form that uses the management and monitoring system of the opening and closing system by loading and unloading control.

A feature of the present invention is an optimized junction box that allows, optionally, its use together with several electronic devices that need a control and voltage management, being preferably applied next to the photovoltaic panels, in order to increase the output voltage of the modules, subject to voltage transients, minimizing surges through a voltage rise system and not decreasing electrical current, through an electronic arrangement, triggered over time, providing an increase in efficiency.

BRIEF DESCRIPTION OF THE FIGURES

[024] Figure 1 shows the main version of the electrical diagram of the circuit arranged in the optimized junction box, detailing the reading, management and voltage control zones and the internal components.

[025] Figure 2 shows the electrical diagram of the circuit arranged in the optimized junction box, showing the current direction with the system closed and connected in series.

[026] Figure 3 shows the electrical diagram of the circuit arranged in the optimized junction box, showing the current direction with the system open and connected in parallel.

[027] Figure 4 shows the electrical diagram of the circuit arranged in the junction box optimized in a version without the provision of zone 1 of the diode set.

[028] Figure 5, 5A and 5B demonstrate the representation of the three constructive variants of the controller device, so that figure 5 details the microcontroller and fsrmware, figure 5A details the use of timers and figure 5B details the opening and closing system for loading and unloading control.

[029] Figure 6 shows the circuit diagram of the second constructive form of the box optimized with electro-electronic or electromechanical components, without using the microcontroller and firmware.

[030] Figure 7 demonstrates a possible replacement between the microcontroller by other electronic or electromechanical components, without using the microcontroller and hardware.

[031] Figures 8, 8A, 8B and 8C demonstrate the laboratory tests applied to the optimized junction box, detailing the benefits and advantages of the product

[032] Figure Ô, 9A, 9B and 9C demonstrate the laboratory tests applied next to the conventional junction box, in order to allow the comparison of the results with the optimized junction box.

DESCRIPTION OF THE INVENTION

[033] The junction box for photovoltaic panels, object of the present invention patent, increases the efficiency of photovoltaic panels, by increasing the voltage and not decreasing the electric current, by means of an electronic circuit comprising diodes, capacitors or ultra capactíores, switches and controller device (microcontroller).

[034] Diodes, as is known in the art, are electronic components that allow the passage of electrical current in only one direction, in the photovoltaic modules are arranged with inverted polarity preventing the modules, during the night, from working in reverse, consuming load or even due to shading during the day, "consume" the power of other modules. [035] Capacitors or ultra capacitors, as is known in the art, are electronic components capable of storing large amounts of electrical charge in less time.

[0361 The commutator, as is known in the art, understood as a commutator regulator, which controls by switching the current and voltage, turning on and off.

[037] The controller or microcontroller device, as is known in the art, is a device that controls the activation of the circuit in relation to the time of loading and unloading and can be a timer microprocessor.

[038] The junction box (100), object of the present invention, has an electronic circuit equipped with an entry point (101) and an exit point (102). The input (101) is the point where the cables from the photovoltaic panel or set of photovoltaic panels are connected, so that the energy generated by the panels is directed to the junction box (100). The output (102) is the point where the voltage managed and controlled by the intelligent electronic circuit of the junction box (100) is directed to storage next to batteries or directed to inverters that will conduct the local or utility grid.

[039] The electronic circuit arranged next to the junction box (100) is separated by 4 (four) zones for reading, managing and controlling the voltage received by the photovoltaic panel. The steps are divided into: set of diodes (10), controller device (microcontroller) (20), set of switches (30) and capacitor arrangement (40).

[040J The set of diodes (10), described as the first stage, is arranged close to the current entry point (101) and aims to objective is to protect the system from a reverse current, as the diodes allow electric current to pass only in one direction.

[041] The controller or microcontroller device (20), described as the second stage, is equipped with a firmware that allows to maintain constant the voltage received by the set of diodes (10), in order to manage and monitor, varying the voltage now in series and pray in parallel. The device (20) is equipped with a voltage regulator (21) that allows filtering and regulating the voltage coming from the set of diodes, regulating the voltage received from the plates in order to avoid a high voltage variation near the device (20), protecting the system from voltage spikes that could result in the microcontroller burning (20). Said regulator (21) is adjusted and regulated according to the need to receive and manage the controlling device (20).

[042] The switch set (30), described as the third stage, is equipped with a first switch A (31) that receives the negative phase of the diode set (10) and directs it to the capacitor arrangement (40), being controlled by the controlling device (20); a second switch B (32) that receives the positive phase of the diode array (10) and directs it to the capacitor array (40), being controlled by the controller device (20); and the third switch C (33) that receives the positive phase of the capacitor array (40) when the system is working in parallel in order to direct to the output point (102) the voltage stored in the capacitor array (40), being controlled by the controlling device (20).

[043] The switches (30) are managed by the controller device (20) in such a way that this device performs constant reading of the switches (31), (32) and (33), alternating the electrical system now in series and now in parallel, in order to keep the voltage constant without the decrease of energy at the exit point (102).

[044] Thus, the switches (30) maintain a constant output voltage in the first switching cycle, doubling the voltage in the next switching cycle, by varying the controller device (20) that alternately turns the connection way on and off and current direction, with the device keeping the circuit open (off) in series for 3 (three) seconds and the closed circuit (on) in parallel for 5 (five) seconds. This alternating system made by the controller device (20) allows that when the circuit is in series (open and off) the current uses the energy stored in the capacitors to direct the same or greater voltage to the outlet point (102), keeping the system more efficient and without considerable losses, in addition to increasing the voltage and stabilizing the electric current at the Vcc output, and when the circuit is in parallel (closed and connected) the current recharges the capacitors and allows this current to be directed with the same input voltage to the exit point (102), resulting in greater efficiency.

[0453 The capacitor arrangement (40), described as the fourth stage, are arranged in two lines with connections in series and in parallel at the same time or individualized, being a mixed or individual connection, which receive the positive and negative phase points of the switch set (30), allowing the current in the circuit to charge the capacitors in order to store energy and transmit the stored energy to the output current next to the point (102). This point of transmission or storage of energy is accomplished by managing the controlling device (20) that alternately keeps the circuit connected in series or in parallel with the power input (101).

The management of the controller device (20) is carried out using the hardware that presents the following information processing steps:

® the voltage regulator (21) is powered by the input (15) where it receives a voltage that can vary between 5v to 30v volts;

® the regulator adjusts the voltage to 12v volts, entering the positive pole at the vtn input of the microcontroller (20) and the negative pole connected to the gnd;

® the positive and negative poles that enter the microcontroller (20) undergo a second regulation, where they are lowered to a voltage of 5V volts, directing a reduced voltage near the 5v input of the microcontroller (20);

• the reduced voltage passes through the digital time or charge control that is programmed with the hardware, according to the pre-determined and necessary time for each situation, where it is alternating between opening and closing (turning on and off);

the voltage is then directed to the switches (31), (32) and (33) through the output at terminal 10 of the microcontroller (20) that control the connections in series and parallel or only series or only parallel of the capacitors (40);

the software manages and monitors the opening time (3 seconds) and closing time (5 seconds), in order to allow the switching of times in series and sometimes in parallel between 3 and 5 seconds, where the system keeps 5 seconds in parallel loading the capacitors (40) and keeps 3 seconds in series unloading the load and improving the efficiency of the panels.

[046] According to highlighted construction points, the mentioned objectives are achieved by the present invention by connecting the optimized junction box (100) to the photovoltaic panel circuit, this interconnection causes a new technical effect that makes the panels performance increase, due to the increase in voltage, by means of the switch set (30) that integrates the arrangement of capacitors or ultra capacitors (40) to the system, sometimes in series, sometimes in parallel, working as an oscillator that stabilizes the Vcc output, avoiding the preventing the decrease of the electric current and improving the performance of the equipment with greater efficiency.

[047] In a second constructive form, the optimized junction box (100) may show a decrease in the number of voltage reading, management and control zones, in order to maintain the same alternating form, now serial and now parallel, and maintaining the same efficiency and tension control.

[048] In this other version, removal of the set of diodes (10) is allowed so that the system can directly receive the voltage from the controller (20) and regulator (21), as mentioned in figure 4.

[049] In a third constructive form, the optimized junction box (100) may show a decrease in the number of reading, management and voltage control zones, in order to maintain the same alternating form, now serial and now parallel, and maintaining the same efficiency and tension control.

[050] In this other version, the controller device (20) is replaced by the controller device (20.1), which is an electro component electronic or electro mechanical known as timer operating as follows:

[051] The device (20.1) receives energy through the input (15.1), where the positive passes through the common contact and the nf contact, feeding the T2 coil and its contacts, where the closed contact goes to the voltage controller (21.1 ) lowering the voltage to 5v volts and supplying the switches (30).

[052] After the time determined in case 3 seconds the open contact closes powered by the Ti coil, and the closed contact opens, turning off the regulator and the switches (30), after 5 seconds of the time programmed in timer T 1 the contact closed, the coil T2 opens and turns the contacts back to the initial position, returning to supply the voltage regulator (21.1) where this cycle is repeated continuously, switching on and off between 3 and 5 seconds or depending on the load and power of the capacitors (40).

[053] This version makes it possible to use it with or without the set of diodes (10) arranged at the entrance of the device, the diodes (10) being optional according to the need for use.

[054] This constructive form is demonstrated and represented in figures 5A and 6.

[055] In a fourth constructive form, the optimized junction box (100) may present a decrease in the number of reading, management and tension control zones, in order to maintain the same alternating form, sometimes series and sometimes parallel, and maintaining the same efficiency and tension control.

[056] In this other version, load control is performed and down rg a (20.2), replacing the time system (3 and 5 seconds), where the voltage regulator (21.2) is powered by the input (15.2) where receives a voltage that can be from 5v to 30v volts so that the regulator will adjust to a voltage of 12v volts entering the vin input of the microcontroller (20) of the positive pole, and the negative in the gnd, where both pass through another regulator internal next to the microcontroller (20) lowering the voltage to 5V volts, directing to output 5v that passes through the voltage control that make the voltage readings of the capacitors (40) through the analog inputs AO and A1, inputs that are programmed by the fjrmware that controls the minimum and maximum voltage of the capacitors (40), where they alternate opening and closing (turning on and off), in order to allow the switching from now in series and now in parallel, improving the efficiency of the panels.

[057] Therefore, the use of a microcontroller (20) equipped with firmware or the use of electro-electronic or electro-mechanical devices, allow the generation of an optimized system that makes it possible to keep the voltage constant, in order to manage and monitor the voltage in the set of switches (30) and next to the capacitor arrangement (40), varying the voltage now in series and now in parallel, resulting in a constant management of the electric current dissipated by the plates in order to avoid a decrease in electric current and allowing an increase in efficiency.

[058] The time of the alternating form of variation, now in parallel and now in series, realized by the system can be dimensioned according to the need of application and use of the junction box, so that the system can be programmed with several variations of however, preferably using a variation of 5 (five) seconds to close in parallel and 3 (three) seconds open in series, because in this way the training in parallel connection and the time in series connection is sufficient to keep the voltage constant and with an increase in efficiency. However, this time can be changed according to the dimensioning of the circuit, modifying the switches (30) and the capacitor arrangement (40).

[059] Gpcíooaimente, the junction box optimized along with its constructive forms, may or may not use the set of diodes (10), depending on the need for application and use of the optimized junction box.

[060] Gpcionalmeníe, the optimized junction box, object of the present invention, can be applied together with several electronic devices that need a voltage control and management, being preferably applied next to the photovoltaic panels, in order to increase the output voltage of the modules, subject to voltage transients, minimizing surges through a voltage rise system and not decreasing electrical current, through an electronic arrangement, triggered over time, providing an increase in efficiency.

TESTS AND LABORATORY

Example 1

[0611 Experimental data were obtained using a solar panel (A) with an optimized junction box (100) object of the present invention and a solar panel (B) with the conventional junction box.

[062] The photovoltaic panels (A) and (B) are the same, having the same power of 330pW (peak Watts) and the same number of cells, with a voltage of 37.8 V (volts), with open circuit and 46.2 V (vofts), with closed circuit "shorted", and current of 8.73 A (ampere), with open circuit and 9.33 A (ampere), with closed circuit "in short", both similar provided by the cells and with an equal surface area of 1.80m ² , with the maximum temperature of 85 ° C, said panels (A) and (B) installed according to the latitude of the place which is 29, 48 ° of inclination, facing the North direction in order to absorb the greatest solar radiation.

[063] The data were obtained on a sunny and cloudy day, with an ambient temperature (in the shade) of 25 ° C, where the optimized junction box (100), object of the present invention, coupled to the photovoltaic panel (A), with a connected load, of a set of 6 lamps of 50 W (watts), the same in series adding 300 W (watts) of installed power.

[064] The following results were observed when the sky was clear without clouds, with the sun full, the electrical current of the charge that was connected to the photovoltaic panel (A) was measured, which was 3.87 A (ampere), the electrical voltage, which was 37.57 V (volts), was also measured, thus obtaining a real power of 145.39 W (watts) at the time of measurement. Simultaneously the photovoltaic panel measurements were made with the conventional junction box (B), with a connected load of a set of 6 lamps of 50 W (watts), the same in series adding 300 W (watts) of installed power. The electric current was 3.45 A (ampere), the electric voltage was 38.42 V (volts), and a real power of 132.54 W (watts) was obtained at the time of measurement. At the time of measurements, it was found that the photovoltaic panel (A) had 9.7% more efficiency than the photovoltaic panel (B).

[065] At another time, with the sky partially covered by clouds at the time of measurements on panels (A) and (B), both with the same installed load that is 300W (watts), it was measured on the panel photovoltaic (A), with the optimized junction box (100) object of the present invention, the electric current of 3.80A (ampere) and a voltage of 26.66v (volts) obtaining a power of 101, 30W (watts), as shown in figures 8, 8A, 8B and SC.

[068] In the photovoltaic panel with the conventional junction box (B), the measurements obtained the following results: electric current of 2.85 A (ampere) and a voltage of 11.68V (volts) resulting in a power of 33, 28W (watts), as shown in figures 0, 9A, 9B and 9C.

[067] It was observed that the photovoltaic panel (A), with the optimized junction box (100) object of the present invention, stabilized the electric current avoiding voltage dip, due to its constructive arrangement, improving the energy efficiency of the panel in 204 , 4% in relation to the power of the photovoltaic panel (B) with the conventional junction box. It was also noticed the intensity of the lamps, where the ones in the panel (A) will remain with their intense brightness proving its efficiency, since those in the panel (B) decreased the brightness intensity of the lamps due to the big drop of electrical voltage.

Example 2

A test performed on a bench, with a stabilized voltage source of 30V (volts) and 5A (ampere) supplying two versions of the optimized junction box, without the set of diodes and with the controller provided by the hardware (figure 4) and without the set of diodes and electromechanical components (figure 6), where we see the following measurements, connecting a load of 300W (watts) of power at the output of the optimized junction box. Measuring the input of the box, we obtained the following measurements: 6.80A and 30V = 198W, and measuring the box output, we had the following measurements: 5, 42 A and 58.32V = 316W. After carrying out this bench test, we found that the optimized junction box presents an increase in efficiency in relation to the input and output.

Claims

CLAIMS:

1. OPTIMIZED JUNCTION BOX comprising a box (1G0) equipped with an electronic circuit that describes an entry point (101) and an exit point (102), characterized in that the electronic circuit is separated by 4 (four) reading zones , voltage management and control, the steps being divided into:

a) set of diodes (10) arranged close to the current entry point (101) in order to protect the system from a reverse current, allowing the passage of electric current in only one direction;

b) controller or microcontroller device (20) equipped with hardware that allows the voltage received by the set of diodes (10) to be kept constant, in order to manage and monitor, varying the voltage now in series and now in parallel or only in series and only in parallel, said device (20) which is equipped with a voltage regulator (21) that allows to filter and regulate the voltage coming from the set of diodes, regulating the voltage received in order to avoid a high voltage variation with the device ( 20), protecting the system from voltage spikes;

c) set of switches (30) provided by a first switch A (31) which receives the negative phase of the set of diodes (10) and directs it to the capacitor arrangement (40), being controlled by the controller device (20); a second switch B (32) that receives the positive phase of the diode array (10) and directs it to the capacitor array (40), being controlled by the controller device (20); and the third switch C (33) that receives the positive phase of the capacitor array (40) when the system is working in parallel in order to direct to the output point (102) the voltage stored in the capacitor array (40), being controlled by controlling device (20);

d) the switches (30) maintain a constant output voltage in the first switching cycle, doubling the voltage in the next switching cycle, by varying the controller device (20) that alternately turns the current connection and direction on and off , and the device keeps the open circuit (off) in series for 3 (three) seconds and the closed circuit (on) in parallel for 5 (five) seconds;

e) capacitor arrangement (40) are arranged in two lines with connections in series and in parallel at the same time or individualized, being a mixed or individual connection, which receive the positive and negative phase points of the set of switches (30), allowing the current in the circuit to charge the capacitors in order to store energy and transmit the stored energy to the output current next to the point (102), this point of transmission or energy storage being performed by the management of the controller device (20 ) that alternately keeps the circuit connected in series or in parallel with the power input (101);

f) when the circuit is in series (open and off) the current uses the energy stored in the capacitors to direct the same or greater voltage to the output point (102), increasing the voltage and stabilizing the electric current at the Vcc output, and when the circuit is in parallel (closed and on) the current recharges the capacitors and allows this current to be directed with the same input voltage to the output point (102 )

2. OPTIMIZED JUNCTION BOX, according to claim 1, characterized in that the regulator (21) is adjusted and regulated according to the need to receive and manage the controller device (20).

3. OPTIMIZED JUNCTION BOX, according to claim 1, characterized in that the switches (30) are managed by the controller device (20) in such a way that this device performs the constant reading of the switches (31), (32) and (33 ), alternating the electrical system now in series and now in parallel, in order to keep the voltage constant or higher, without decreasing the energy at the outlet point (102).

4. OPTIMIZED JUNCTION BOX, according to claim 1, characterized in that the electronic circuit arranged next to the junction box (100) is separated by 4 (four) zones divided into: diode set (10), controller device (microcontroller) ) (20), set of switches (30) and capacitor arrangement (40).

5. OPTIMIZED JUNCTION BOX, characterized by the controller device (20) equipped with firmware to manage and process information as follows:

a) the voltage regulator (21) is powered by the input (15) where it receives a voltage that can vary between 5v to 30v voits; b) the regulator adjusts the voltage to 12v volts, entering the positive pole at the niicrocontrofor input (20) and the negative pole connected to the gnd;

c) the positive and negative poles that enter the microcontroller (20) pass through a second regulation, where they are lowered to a voltage of 5V volts, directing a reduced voltage near the 5v input of the microcontroller (20); d) the reduced voltage passes through the digital time control or load that is programmed with the firmware, according to the pre-determined and necessary time or load for each situation, where it is alternating in opening and closing (turning on and off);

e) the voltage is then directed to the switches (31), (32) and (33) through the output at terminal 10 of the microcontroller (20) that control the connections in series and parallel or only series or only parallel of the capacitors (40 );

f) the firmware manages and monitors the opening time (3 seconds) closing time (5 seconds), in order to allow the switching of times in series and sometimes in parallel between 3 and 5 seconds, where the system keeps 5 seconds (closed) in parallel charging the capacitors (40) maintaining the same output current and maintaining 3 seconds (open) in series discharging the load in order to maintain or increase the output voltage.

6. GTffVHZADA JUNCTION BOX, according to claim 5, characterized in that the electronic circuit allows the generation of an increase in voltage, through the switch set (30) that integrates the arrangement of capacitors or ultra capacitors (40) to the system now in series and now in parallel, working as an oscillator that stabilizes the Vcc output, avoiding the impediment of decreasing the electric current, keeping the voltage constant or increasing the output voltage.

7. OPTIMIZED JUNCTION BOX, according to claims 1 and 5, characterized in that, in a second constructive form, the optimized junction box (100) has a decrease in the number of voltage reading, management and control zones, so to maintain the same alternating shape, sometimes series and sometimes parallel, where the set of diodes (10) is removed so that the system can directly receive the voltage next to the controller (20) and regulator (21).

8. OPTIMIZED JUNCTION BOX, according to claims 1 and 5, and characterized in a third constructive way, the optimized junction box (100) presents a decrease in the number of voltage reading, management and control zones, so to maintain the same alternating shape, sometimes series and sometimes parallel, where the controller device (20) is replaced by the controller device (20.1), which is an electronic or mechanical mechanical component, functioning as follows; a) the device (20.1) receives energy through the input (15.1), where the positive passes through the common contact and through the nf contact, feeding the T2 coil and its contacts, where the closed contact goes to the voltage controller (21.1) lowering the voltage to 5v volts and supplying the switches (30);

b) after the time determined in case 3, the open contact closes, powered by the TI coil. and the closed contact opens, turning off the regulator and the switches (30), after 5 seconds of the time programmed in the TI timer, the closed contact opens and turns off the coil T2 causing the contacts to return to the initial position, returning to supply the voltage regulator (211) where this cycle is repeated continuously, turning on and off between 3 and 5 seconds or depending on the load and power of the capacitors (40).

c) makes it possible to use it with or without the set of diodes (10) arranged at the entrance of the device, the diodes (10) being optional according to the need for use.

9. OPTIMIZED JUNCTION BOX, according to claims 1 and 5, characterized in that in a fourth constructive form, the optimized junction box (100) presents a decrease in the number of voltage reading, management and control zones, where the charge and discharge control (20.2), replaces the time system (3 and 5 seconds) working as follows:

a) the voltage regulator (21.2) is powered by the input (15.2) where it receives a voltage that can be from 5v to 30v volts so that the regulator will adjust to a voltage of 12v volts entering the microcontroller vin input (20 ) of the positive pole, and the negative pole in the gnd, where both pass through another internal regulator next to the microcontroller (20) lowering the voltage to 5V volts;

b) directing to output õv that passes through the voltage control that read the capacitor voltages (40) through the analog inputs A0 and A1, inputs that are programmed by the fmnware that controls the minimum and maximum voltage of the capacitors (40), where keeps alternating opening and closing (switching on and off), in order to allow switching between series and parallel, improving the efficiency of the panels.

10. OPTIMIZED JUNCTION BOX, according to claims 1 and 5, characterized by the use of a microconfroller (20) equipped with firmware or the use of electro-electronic or electro-mechanical devices, allowing the generation of an optimized system that allows keep the voltage constant, in order to manage and monitor the voltage in the set of switches (30) and next to the capacitor arrangement (40), varying the voltage now in series and now in parallel, resulting in a constant management of the dissipated electric current the plates in order to avoid a decrease in electric current and allowing an increase in efficiency.

11. OPTIMIZED JUNCTION BOX, according to claims 1 and 5, characterized in that the time of the alternating form of variation from now to parallel and now in series carried out by the system can be dimensioned according to the need for application and use of the box junction, so that the system can be programmed with different time variations, but preferably using a variation of 5 (five) seconds to close in parallel and 3 (three) seconds open in series, because in this way the loading time capacitors in parallel connection and the time in series connection is sufficient to keep the voltage constant and with increased efficiency.

12. OPTIMIZED JUNCTION BOX, according to claim 11, characterized by the time being changed according to the dimensioning of the circuit, modifying the switches (30) and the capacitor arrangement (40).

13. OPTIMIZED JUNCTION BOX, according to claims 1 and 5, characterized by optionally, the junction box optimized next to its constructive forms, may or may not use the set of diodes (10). depending on the application need and use of the optimized junction box.

14. OPTIMIZED JUNCTION BOX, according to claims 1 and 5, characterized by optionally, the optimized junction box, can be applied together with several electronic devices that need a voltage control and management, being preferably applied next to the panels photovoltaic, in order to increase the output voltage of the modules, subject to voltage transients, minimizing surges through a voltage lifting system and not decreasing electrical current, by means of an electronic arrangement, triggered over time or load.