KR20200092736A - Solar photovoltaic system - Google Patents

Abstract

Provided is a solar photovoltaic system which can reliably switch between a constant current charging method and a constant voltage charging method. The solar photovoltaic system comprises: a storage battery; a solar panel which generates power by photoelectric conversion of sunlight; and a charge controller which selectively charges the storage battery by using the power in a constant current charging method or a constant voltage charging method. The charge controller charges the storage battery by the constant voltage charging method when a storage amount of the storage battery increases by a first hysteresis amount from a reference storage amount, and charges the storage battery by the constant current charging method when the storage amount of the storage battery decreases by a second hysteresis amount from the reference storage amount. Moreover, the charge controller changes the first hysteresis amount based on a rate of increase in the storage amount of the storage battery when the storage amount of the storage battery increases and reaches the reference storage amount, and changes the second hysteresis amount based on the rate of decrease in the storage amount of the storage battery when the storage amount of the storage battery decreases and reaches the reference storage amount.

Description

Solar Power System {SOLAR PHOTOVOLTAIC SYSTEM}

The present invention relates to a solar power system. More specifically, the present invention relates to a photovoltaic power generation system comprising a storage battery, a solar panel and a charge controller.

Recently, as the problem of environmental pollution and depletion of natural resources has emerged, interest in a photovoltaic power generation system using solar power has increased. In general, a photovoltaic power generation system includes a solar panel that produces electricity by photoelectrically converting sunlight, a storage battery that stores the electricity, and a charging controller that controls the operation of storing the electricity in the storage battery. Meanwhile, the charge controller generates a step-down voltage by stepping down the voltage output from the solar panel with a buck-converter, and charges the battery by supplying the step-down voltage generated by the buck-converter to the battery. can do. At this time, in the conventional photovoltaic power generation system, the charging controller charges the battery with a constant current charging method capable of high-speed charging when the battery storage amount is less than the reference storage amount (in this case, maximum power point tracking) ; MPPT), and if the storage capacity of the storage battery is greater than or equal to the standard storage capacity, charge the storage battery by charging it with a constant voltage charging method capable of fully charging (i.e., buffering), thereby controlling the storage battery to be charged relatively quickly and completely. Can. However, it is common that electricity is stored in the storage battery (for example, solar power generation is performed during the daytime) and electricity stored in the storage battery is used (for example, a household appliance is used during the daytime), and accordingly, In a conventional photovoltaic power generation system that changes the charging method by comparing the amount of storage of a battery with the amount of storage, the storage amount of the storage battery is near the standard storage amount. When there is, the charging method of the storage battery is frequently switched over than necessary, and a high load may be applied to the charging controller or a malfunction may occur.

One object of the present invention is that electricity is stored in the storage battery and the electricity stored in the storage battery is used at the same time, even if the storage capacity of the storage battery fluctuates near the standard storage capacity, the charging method of the storage battery can be stably switched between the constant current charging method and the constant voltage charging method. It is to provide a photovoltaic power generation system. However, the object of the present invention is not limited to the above-described object, and may be variously extended without departing from the spirit and scope of the present invention.

In order to achieve one object of the present invention, a photovoltaic power generation system according to embodiments of the present invention comprises at least one storage battery, a solar panel for photoelectrically converting sunlight to produce power, and the storage battery using the power It may include a charging controller to selectively charge by a constant current charging method or a constant voltage charging method. At this time, the charge controller charges the battery with the constant voltage charging method when the amount of storage of the battery increases by a first hysteresis amount from the reference amount of electricity, and the amount of electricity stored by the second amount of power from the reference amount of power When the amount decreases, the storage battery can be charged using the constant current charging method. In addition, the charging controller changes the first history power storage amount based on the increasing speed of the power storage amount when the power storage amount increases and reaches the reference power storage amount, and when the power storage amount decreases and reaches the reference power storage amount, the The second history power storage amount may be varied based on a reduction speed of the power storage amount.

According to an embodiment, the charge controller may reduce the first history power storage amount if the increase speed of the power storage amount is faster than a reference increase speed.

According to an embodiment, the amount of reduction in the first history power storage amount may be proportional to a value obtained by subtracting the reference increase speed from the increase speed of the power storage amount.

According to an embodiment, the charge controller may increase the first history power storage amount when the increase speed of the power storage amount is slower than a reference increase speed.

According to an embodiment, the amount of increase in the first hysteretic power storage amount may be proportional to a value obtained by subtracting the increase speed of the power storage amount from the reference increase speed.

According to an embodiment, the charging controller may reduce the second history power storage amount when the reduction speed of the power storage amount is faster than a reference reduction speed.

According to an embodiment, the amount of reduction in the second history amount of power storage may be proportional to a value obtained by subtracting the reference reduction speed from the rate of reduction of the amount of power storage.

According to one embodiment, the charge controller may increase the second history power storage amount if the reduction speed of the power storage amount is slower than a reference reduction speed.

According to an embodiment, the amount of increase in the second history power storage amount may be proportional to a value obtained by subtracting the reduction speed of the power storage amount from the reference reduction speed.

The photovoltaic power generation system according to embodiments of the present invention includes a storage battery, a solar panel for photoelectrically converting sunlight, and a charging controller for selectively charging the storage battery using a constant current charging method or a constant voltage charging method using the power Containing, when the storage capacity of the storage battery increases by the first amount of power storage from the reference storage amount, charges the storage battery with a constant voltage charging method, and when the storage capacity of the storage battery decreases by the second storage power storage amount from the reference storage amount, the constant battery charging method Charge, and if the storage capacity of the storage battery increases and the reference storage capacity is reached, the first hysteresis is varied based on the rate of increase in the storage capacity of the storage battery, and the storage capacity of the storage battery decreases while the storage capacity of the storage battery reaches the storage capacity. By varying the second history power storage amount based on the rate of decrease in the amount, when the electricity is stored in the storage battery and electricity stored in the storage battery is used, the charging method of the storage battery is a constant current charging method even if the storage amount of the storage battery fluctuates near the standard storage amount. It can stably switch between over-voltage charging methods. Thus, the photovoltaic power generation system can prevent the battery charging method from being frequently switched more than necessary in a situation where the storage amount of the storage battery is fluctuating near the reference storage amount, and accordingly, a high load is applied to the charging controller or a failure occurs. This can be prevented from occurring. However, the effects of the present invention are not limited to the above-described effects, and may be variously extended without departing from the spirit and scope of the present invention.

1 is a block diagram showing a solar power system according to embodiments of the present invention.
2A and 2B are diagrams for explaining that the solar power system of FIG. 1 switches a charging method of a storage battery.
FIG. 3A is a diagram illustrating an example in which the amount of power stored in the first hysteresis is increased in the solar power system of FIG. 1.
FIG. 3B is a diagram illustrating an example in which the first amount of power storage is reduced in the solar power system of FIG. 1.
FIG. 4A is a diagram showing an example in which the amount of storage of the second hysteresis is increased in the solar power system of FIG. 1.
FIG. 4B is a diagram illustrating an example in which the amount of storage of the second hysteresis in the solar power system of FIG. 1 is reduced.

With respect to the embodiments of the present invention disclosed in the text, specific structural or functional descriptions are exemplified only for the purpose of illustrating the embodiments of the present invention, and the embodiments of the present invention can be implemented in various forms and the text It should not be construed as being limited to the embodiments described in.

The present invention can be applied to various changes and may have various forms, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to specific disclosure forms, and it should be understood that all modifications, equivalents, and substitutes included in the spirit and scope of the present invention are included.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms may be used for the purpose of distinguishing one component from other components. For example, the first component may be referred to as the second component without departing from the scope of the present invention, and similarly, the second component may also be referred to as the first component.

When an element is said to be "connected" or "connected" to another component, it is understood that other components may be directly connected to or connected to the other component, but there may be other components in between. It should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle. Other expressions describing the relationship between the components, such as "between" and "immediately between" or "neighboring" and "directly neighboring to" should be interpreted as well.

The terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms “include” or “have” are intended to indicate that a feature, number, step, action, component, part, or combination thereof is described, and that one or more other features or numbers are present. It should be understood that it does not preclude the existence or addition possibility of steps, actions, components, parts or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person skilled in the art to which the present invention pertains. Terms, such as those defined in a commonly used dictionary, should be interpreted as meanings consistent with meanings in the context of related technologies, and should not be interpreted as ideal or excessively formal meanings unless explicitly defined in the present application. .

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same components in the drawings, and duplicate descriptions for the same components are omitted.

1 is a block diagram illustrating a photovoltaic system according to embodiments of the present invention, and FIGS. 2A and 2B are diagrams for explaining that the photovoltaic system of FIG. 1 switches a charging method of a storage battery.

1 to 2B, the photovoltaic power generation system 100 may include at least one storage battery 120, a solar panel 140, and a charge controller 160. At this time, the solar power generation system 100 may be installed in a building (eg, a home, a building, etc.).

The storage battery 120 may be charged with power (POW) supplied from the solar panel 140. In addition, the storage battery 120 may provide stored electricity to at least one electrical facility in the building. For example, the storage battery 120 may provide stored electricity in the form of direct current (DC) to the electrical installation or convert it to alternating current (AC). At this time, the storage battery 120 may store electricity by the charging and provide the stored electricity to the electrical installation. Also, the storage battery 120 may provide storage battery information INF, such as a storage amount, an increase rate of the storage amount, and a decrease rate of the storage amount, to the charge controller 160. Meanwhile, in FIG. 1, for convenience of description, the photovoltaic system 100 is illustrated as including one storage battery 120, but according to an embodiment, the photovoltaic system 100 includes a plurality of storage batteries 120 ). In this case, the plurality of storage cells 120 may be connected to each other in parallel and/or series.

The solar panel 140 may photoelectrically convert sunlight to produce power (POW). To this end, the solar panel 140 may include at least one solar cell. The solar cell may generate power (POW) by performing photoelectric conversion on sunlight incident on the solar panel 140. In one embodiment, the solar cell may be a crystalline solar cell (eg, a solar cell manufactured by drawing a circuit on a wafer in which polysilicon is sliced). In this case, the solar cell has the advantage that the photoelectric conversion efficiency is relatively high, but has the disadvantage that the manufacturing cost is high and there are many restrictions on the installation location. In another embodiment, the solar cell may be a thin film solar cell (eg, a solar cell manufactured by thinly applying a compound material having photoelectric conversion properties on a substrate such as glass, plastic, etc.). In this case, the solar cell has the advantage that the manufacturing cost is low and there are few restrictions on the installation location, but it has the disadvantage that the photoelectric conversion efficiency is relatively low. For example, the compound material may be a material made of polysilicon in a gas form (in this case, the solar cell is called an amorphous silicon thin film solar cell). For another example, the compound is a compound of copper (Cu), indium (In), gallium (Ga), selenium (Se) (or part of selenium (Se) can be replaced with sulfur (S)) (in this case) , Solar cells may be referred to as ICGS thin film solar cell). However, this is an example, and the type of the solar cell is not limited thereto.

The charging controller 160 selectively charges the storage battery 120 with the constant current charging method 220 or the constant voltage charging method 240 (that is, displayed as CTL) by using the power (POW) produced by the solar panel 140. )can do. That is, as illustrated in FIG. 2B, the charging controller 160 may switch the charging method for charging the storage battery 120 between the constant current charging method 220 and the constant voltage charging method 240. At this time, the constant current charging method 220 may charge the storage battery 120 at a higher speed than the constant voltage charging method 240, and perform maximum power point tracking (MPPT) to obtain maximum power from the solar panel 140. Can be extracted. Therefore, when the storage battery 120 is charged by the constant current charging method 220, the storage amount of the storage battery 120 can be rapidly increased. However, the constant current charging method 220 has a limitation in that if the amount of storage of the storage battery 120 exceeds a certain level, it causes overcharging to shorten the life of the storage battery 120 and does not fully charge the storage battery 120. On the other hand, the constant voltage charging method 240 can stably charge the battery 120 (ie, prevent overcharge), and fully charge the battery 120. Therefore, when the storage battery 120 is charged by the constant voltage charging method 240, the storage battery 120 may be charged to the maximum capacity MAX of the storage battery 120. However, the constant voltage charging method 240 has a limitation in charging the storage battery 120 at a low speed compared to the constant current charging method 220.

Thus, in the conventional solar power system, the charge controller 160 charges the storage battery 120 by the constant current charging method 220 when the storage amount of the storage battery 120 is smaller than the reference storage amount (RAE), and the storage battery 120 If the power storage amount of the battery is greater than or equal to the reference power storage amount (RAE), the battery 120 is charged by a constant voltage charging method, but the storage battery 120 is charged in a situation where the power storage amount fluctuates near the reference power storage amount (RAE). The charging method is frequently switched over than necessary, causing a high load on the charging controller 160 or a failure. In order to solve this problem, in the photovoltaic system 100, when the charge controller 160 increases the amount of power stored in the storage battery 120 from the reference power storage amount (RAE) by the first history power storage amount (FHP), the storage battery 120 Is charged by the constant voltage charging method 240, and when the amount of power storage of the storage battery 120 decreases from the reference power storage amount (RAE) by the second history power storage amount (SHP), the storage battery 120 is charged by the constant current charging method 220. Can. In other words, the charging controller 160 may have a hysteresis section (FHP+SHP) in switching the charging method of the storage battery 120 between the constant current charging method 220 and the constant voltage charging method 240. Specifically, the charge controller 160 increases the amount of storage of the battery 120 by the first amount of storage (FHP) from the reference amount of storage (RAE) as the amount of storage of the battery 120 increases (that is, represented by CA) If (ie, indicated by TA), the storage battery 120 can be charged by the constant voltage charging method 240. Accordingly, the storage battery 120 is charged at a low speed, but may be charged to the maximum capacity MAX of the storage battery 120. In addition, the charge controller 160 decreases the amount of storage of the battery 120 by the second amount of storage (SHP) from the reference amount of storage (RAE) as the amount of storage of the battery 120 decreases (that is, indicated by DA) ( That is, if it is expressed in TB), the storage battery 120 can be charged by the constant current charging method 220. Accordingly, the storage battery 120 can be charged at a high speed. According to an embodiment, the charge controller 160 may vary a reference power storage amount (RAE) to be compared with the power storage amount of the storage battery 120 according to a required condition.

For example, as illustrated in FIG. 2A, even if the amount of storage of the battery 120 increases as the amount of storage of the battery 120 increases (ie, indicated by CA), the storage battery 120 ) If the amount of power storage is not additionally increased by the first amount of power storage (FHP) from the reference power storage (RAE), the charging controller 160 changes the charging method of the storage battery 120 from the constant current charging method 220 to the constant voltage charging method ( 240). In other words, the charging controller 160 increases the storage capacity of the storage battery 120 even if the storage capacity of the storage battery 120 reaches the reference power storage amount (RAE) as the storage capacity of the storage battery 120 increases (that is, indicated as CA). It does not switch directly from the constant current charging method 220 to the constant voltage charging method 240. Also, as illustrated in FIG. 2A, even if the amount of storage of the storage battery 120 decreases below the reference amount of storage (RAE) as the amount of storage of the storage battery 120 decreases (that is, indicated by DA), the storage battery 120 If the power storage amount does not further decrease from the reference power storage amount (RAE) by the second history power storage amount (SHP), the charging controller 160 changes the charging method of the storage battery 120 from the constant voltage charging method 240 to the constant current charging method 220 Do not switch to In other words, the charge controller 160 may charge the battery 120 even if the storage amount of the storage battery 120 reaches the reference storage amount (RAE) as the storage amount of the storage battery 120 decreases (that is, indicated as DA). It does not switch directly from the constant voltage charging method 240 to the constant current charging method 220. As described above, the charging controller 160 puts a history section (FHP+SHP) in switching the charging method of the storage battery 120 between the constant current charging method 220 and the constant voltage charging method 240, thereby accumulating the storage battery 120 When electricity is stored at the same time as electricity stored in the storage battery 120 is used, the charging method of the storage battery 120 is the constant current charging method 220 and the constant voltage charging even if the storage amount of the storage battery 1200 fluctuates near the reference storage amount (RAE). It is possible to prevent switching between the schemes 240 more than necessary.

Furthermore, the charging controller 160 increases the amount of storage of the storage battery 120 (that is, expressed as CA) and reaches the reference power storage amount RAE, and the first history power storage based on the increase rate of the storage amount of the storage battery 120 When the amount FHP is varied and the storage amount of the storage battery 120 decreases (that is, indicated as DA) and reaches the reference storage amount RAE, the second history power storage based on the decrease rate of the storage amount of the storage battery 120 The amount (SHP) can be varied. In other words, the charging controller 160 increases or decreases the first history power storage amount FHP according to how quickly the power storage amount of the rechargeable battery 120 increases, and the second history depending on how fast the power storage amount of the rechargeable battery 120 decreases. It is to increase or decrease the power storage amount (SHP). Specifically, the charge controller 160 is a constant voltage charging the battery 120 when the rate of increase of the amount of storage of the battery 120 is faster than the reference increase rate when the amount of storage of the battery 120 increases (ie, indicated as CA) It is determined that charging by the method 240 is urgent, and accordingly, the first hysteresis amount FHP can be reduced. At this time, the amount of reduction of the first hysteresis power storage amount FHP may be proportional to a value obtained by subtracting a reference increase speed from an increase rate of the power storage amount of the storage battery 120. That is, as the rate of increase in the amount of storage of the storage battery 120 increases, the amount of decrease in the first hysteresis storage amount (FHP) increases, and accordingly, the charging method of the storage battery 120 is a constant voltage charging method in the constant current charging method 220 ( 240) may be advanced. On the other hand, the charge controller 160 when the amount of storage of the storage battery 120 increases (that is, represented by CA) when the rate of increase of the storage amount of the storage battery 120 is slower than the reference increase rate, constant charging the battery 120 It is determined that it is more necessary to charge the method 220, and accordingly, the first hysteresis amount FHP may be increased. At this time, the amount of increase in the first hysteretic power storage amount FHP may be proportional to the reference increase rate minus the increase rate of the power storage amount of the storage battery 120. That is, as the rate of increase in the amount of storage of the storage battery 120 is slow, the amount of increase in the first hysteretic storage amount (FHP) increases, and accordingly, the charging method of the storage battery 120 is a constant voltage charging method in the constant current charging method 220 ( 240) may be delayed.

In addition, the charge controller 160 when the amount of storage of the battery 120 is reduced (that is, indicated as DA), the rate of reduction of the amount of storage of the battery 120 is faster than the reference reduction rate, the battery 120 is a constant current charging method It is judged that it is urgent to charge with 220, and accordingly, the second hysteresis amount SHP can be reduced. At this time, the reduction amount of the second hysteresis power storage amount SHP may be proportional to a value obtained by subtracting the reference reduction speed from the reduction rate of the storage capacity of the storage battery 120. That is, the faster the reduction rate of the storage amount of the storage battery 120, the larger the reduction amount of the second hysteresis storage capacity (SHP), and accordingly, the charging method of the storage battery 120 is a constant current charging method in the constant voltage charging method 240 ( 220) may be advanced. On the other hand, the charge controller 160 when the amount of storage of the battery 120 decreases (that is, indicated as DA), the rate of decrease of the amount of storage of the battery 120 is slower than the reference reduction rate, the battery 120 is charged with a constant voltage It is determined that it is necessary to charge the system 240 more, and accordingly, the second hysteresis amount SHP may be increased. At this time, the amount of increase in the second hysteresis amount SHP may be proportional to a value obtained by subtracting the reduction rate of the amount of storage of the battery 120 from the reference reduction rate. That is, the slower the rate of decrease in the amount of storage of the storage battery 120, the greater the amount of increase in the second hysteresis storage capacity (SHP), and accordingly, the charging method of the storage battery 120 is a constant current charging method in the constant voltage charging method 240 ( 220) may be delayed. In this way, the charging controller 160 changes the history section (FHP+SHP) in switching the charging method of the storage battery 120 between the constant current charging method 220 and the constant voltage charging method 240, thereby accumulating the storage battery 120 When it is more necessary to charge the constant current charging method 220, the time for charging the storage battery 120 with the constant current charging method 220 may be increased, and it is more preferable to charge the storage battery 120 with the constant voltage charging method 240. When necessary, the time for charging the storage battery 120 by the constant voltage charging method 240 may be increased. Accordingly, the charging controller 160 can efficiently charge the storage battery 120 according to a given situation.

As described above, the photovoltaic power generation system 100 uses a constant current to the storage battery 120, the solar panel 140 for photoelectrically converting sunlight to produce power (POW), and the storage battery 120 using the power (POW). It includes a charging controller 160 for selectively charging by the charging method 220 or the constant voltage charging method 240, and the power storage amount of the storage battery 120 is increased from the reference power storage amount (RAE) by the first history power storage amount (FHP) When the storage battery 120 is charged with the constant voltage charging method 240, and when the storage amount of the storage battery 120 decreases from the reference storage amount RAE by the second history storage amount SHP, the storage battery 120 is charged with the constant current charging method ( 220), when the storage power of the storage battery 120 increases and reaches the reference power storage amount (RAE), the first hysteresis power storage amount (FHP) is varied based on the increase rate of the storage power of the storage battery 120, and the storage battery Electricity is stored in the storage battery 120 by varying the second hysteresis storage amount SHP based on the reduction rate of the storage amount of the storage battery 120 when the reference storage amount RAE is reached while the storage amount of the storage 120 decreases At the same time, when the electricity stored in the storage battery 120 is used, the charging method of the storage battery 120 is a constant current charging method 220 and a constant voltage charging method 240 even if the storage amount of the storage battery 120 is fluctuating near the reference storage amount (RAE). ). Accordingly, the photovoltaic power generation system 100 can prevent the charging method of the storage battery 120 from being frequently switched more than necessary in a situation where the storage amount of the storage battery 120 is fluctuating near the reference storage amount (RAE). Accordingly, it is possible to prevent a high load or a failure from occurring in the charge controller 160, and it is possible to efficiently charge the storage battery 120 according to a given situation.

FIG. 3A is a view showing an example in which the first amount of power storage is increased in the photovoltaic power generation system of FIG. 1, and FIG. 3B is a diagram showing an example in which the first amount of power storage is reduced in the solar power system of FIG. 1.

Referring to FIGS. 3A and 3B, when the amount of storage of the storage battery 120 increases, the charging controller 160 increases the storage speed of the storage battery 120 according to whether the increase rate of the storage amount is faster or slower than the reference increase rate. The amount (FHP) can be reduced or increased. Specifically, as illustrated in FIG. 3A, when an increase rate of the amount of storage of the storage battery 120 is slower than a reference increase rate when the amount of storage of the storage battery 120 increases, the charging controller 160 supplies the storage battery 120 with a constant current. It may be determined that it is more necessary to charge the charging method 220. In other words, when the amount of storage of the storage battery 120 increases, the charge controller 160 is slower than the reference increase rate of the storage amount of the storage battery 120 (that is, when the storage amount of the storage battery 120 slowly increases) ), rather than stably charging the battery 120, it is determined that it is necessary to charge the battery 120 at a high speed. Accordingly, the charging controller 160 may increase the first hysteresis amount FHP by the first increase amount d1 (ie, increase from FHP1 to FHP2). As a result, as the first hysteresis amount FHP increases (i.e., by the first increase amount d1), the storage amount of the storage battery 120 must be increased to increase the charging method of the storage battery 120 in the constant current charging method 220. Since it is switched to the constant voltage charging method 240, the time point at which the charging method of the storage battery 120 is switched from the constant current charging method 220 to the constant voltage charging method 240 may be delayed (that is, the storage battery 120 has a constant current charging method). (220) has the effect of increasing the charging time). On the other hand, the first increase amount d1 may be proportional to a value obtained by subtracting the increase rate of the storage amount of the storage battery 120 from the reference increase rate. That is, as the rate of increase in the storage amount of the storage battery 120 is slow, the first increase amount d1 increases, and accordingly, the charging method of the storage battery 120 is switched from the constant current charging method 220 to the constant voltage charging method 240. The point in time can be delayed.

On the other hand, as illustrated in FIG. 3B, when the increase rate of the amount of storage of the storage battery 120 is faster than the reference increase rate when the amount of storage of the storage battery 120 increases, the charging controller 160 supplies the storage battery 120 with a constant voltage. It may be determined that charging by the charging method 240 is urgent. In other words, when the amount of storage of the battery 120 increases, the charge controller 160 increases the amount of storage of the battery 120 faster than the reference increase rate (that is, the amount of storage of the battery 120 increases rapidly) If), rather than charging the battery 120 at a high speed, it is determined that it is more necessary to stably charge the battery 120 (ie, to prevent overcharging) and to fully charge the battery 120. Accordingly, the charging controller 160 may decrease the first hysteresis amount FHP by the second reduction amount d2 (ie, decrease from FHP1 to FHP2). As a result, even if the amount of storage of the storage battery 120 increases as the first hysteretic storage amount FHP decreases (that is, by the second decrease amount d2), the charging method of the storage battery 120 is the constant current charging method 220 Since it is switched to the constant voltage charging method 240, the time point when the charging method of the storage battery 120 is switched from the constant current charging method 220 to the constant voltage charging method 240 may be advanced (that is, the storage battery 120 is the constant voltage charging method) (240) has the effect of increasing the charging time). Meanwhile, the second reduction amount d2 may be proportional to a value obtained by subtracting a reference increase speed from an increase rate of the power storage amount of the storage battery 120. That is, as the rate of increase in the amount of storage of the storage battery 120 increases, the second decrease amount d2 increases, and accordingly, the charging method of the storage battery 120 is switched from the constant current charging method 220 to the constant voltage charging method 240. The point in time can be accelerated. As described above, the charging controller 160 charges the storage battery 120 with the constant current charging method 220 when it is more necessary to charge the storage battery 120 with the constant current charging method 220 when the power storage amount of the storage battery 120 increases. If it is necessary to charge the battery 120 with the constant voltage charging method 240, the time for charging the battery 120 with the constant voltage charging method 240 can be increased.

FIG. 4A is a diagram illustrating an example in which the amount of storage of the second hysteresis in the photovoltaic system of FIG. 1 is increased, and FIG. 4B is a diagram illustrating an example in which the amount of storage of the second hysteresis in the photovoltaic system of FIG. 1 is decreased.

4A and 4B, when the amount of storage of the storage battery 120 decreases, the charge controller 160 stores the second history according to whether the reduction rate of the storage amount of the storage battery 120 is faster or slower than the reference reduction rate. The amount (SHP) can be reduced or increased. Specifically, as illustrated in FIG. 4A, when the reduction rate of the storage amount of the storage battery 120 is slower than the reference reduction rate when the storage amount of the storage battery 120 decreases, the charging controller 160 supplies the storage battery 120 with a constant voltage. It may be determined that it is more necessary to charge the charging method 240. In other words, when the amount of power storage of the storage battery 120 decreases, the charge controller 160 is slower than the reference reduction speed (ie, when the power storage amount of the storage battery 120 slowly decreases) ), rather than charging the storage battery 120 at a high speed, it is determined that it is more necessary to stably charge the storage battery 120 (ie, to prevent overcharging) and to fully charge the storage battery 120. Accordingly, the charge controller 160 may increase the second hysteresis amount SHP by the first increase amount d1 (ie, increase from SHP1 to SHP2). As a result, as the second hysteresis amount SHP increases (i.e., by the first increase amount d1), the storage amount of the storage battery 120 must be further reduced, so that the charging method of the storage battery 120 is performed by the constant voltage charging method 240. Since it is switched to the constant current charging method 220, the time point at which the charging method of the storage battery 120 is switched from the constant voltage charging method 240 to the constant current charging method 220 may be delayed (that is, the storage battery 120 is charged with the constant voltage charging method). (240) has the effect of increasing the charging time). On the other hand, the first increase amount d1 may be proportional to a value obtained by subtracting the decrease rate of the storage amount of the storage battery 120 from the reference decrease rate. That is, as the rate of decrease in the amount of storage of the storage battery 120 decreases, the first increase amount d1 increases, and accordingly, the charging method of the storage battery 120 is switched from the constant voltage charging method 240 to the constant current charging method 220. The point in time can be delayed.

On the other hand, as illustrated in FIG. 4B, when the amount of reduction of the amount of storage of the battery 120 is faster than the reference reduction rate when the amount of storage of the battery 120 decreases, the charging controller 160 supplies the battery 120 with a constant current. It can be determined that it is urgent to charge the charging method 220. In other words, when the amount of storage of the storage battery 120 decreases, the charge controller 160 is faster than the reference reduction rate (ie, the storage capacity of the storage battery 120 rapidly decreases) If), rather than stably charging the battery 120, it is determined that it is more necessary to charge the battery 120 at a high speed. Accordingly, the charging controller 160 may reduce the second hysteresis amount SHP by the second reduction amount d2 (ie, decrease from SHP1 to SHP2). As a result, even if the amount of storage of the battery 120 decreases as much as the second hysteresis amount SHP decreases (i.e., by the second decrease amount d2), the charging method of the battery 120 is the constant voltage charging method 240 Since it is switched to the constant current charging method 220, the time when the charging method of the storage battery 120 is switched from the constant voltage charging method 240 to the constant current charging method 220 may be advanced (that is, the storage battery 120 is a constant current charging method) (220) has the effect of increasing the charging time). On the other hand, the second reduction amount d2 may be proportional to a value obtained by subtracting the reference reduction speed from the reduction rate of the power storage amount of the storage battery 120. That is, the faster the reduction rate of the storage amount of the storage battery 120, the second decrease amount (d2) becomes larger, and accordingly, the charging method of the storage battery 120 is switched from the constant voltage charging method 240 to the constant current charging method 220 The point in time can be accelerated. As described above, the charging controller 160 charges the storage battery 120 with the constant current charging method 220 when it is more necessary to charge the storage battery 120 with the constant current charging method 220 when the amount of storage of the storage battery 120 decreases. If it is necessary to charge the battery 120 with the constant voltage charging method 240, the time for charging the battery 120 with the constant voltage charging method 240 can be increased.

The present invention can be widely applied to photovoltaic power generation systems including a storage battery, a solar panel, and a charge controller. On the other hand, in the above, the present invention has been described with reference to embodiments, but those skilled in the art variously modify and change the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You can understand that you can.

100: solar power system 120: storage battery
140: solar panel 160: charge controller
POW: Electric power INF: Battery information
FHP: 1st history power storage amount SHP: 2nd history power storage amount
RAE: Reference power storage

Claims (9)

At least one storage battery;
A solar panel that produces electricity by photoelectrically converting sunlight; And
And a charging controller for selectively charging the storage battery using a constant current charging method or a constant voltage charging method using the power,
The charge controller charges the battery in the constant voltage charging method when the amount of storage of the battery increases from the reference amount of storage by a first history amount of storage, and when the amount of storage decreases by the second amount of history of storage from the reference amount of storage by the storage battery To charge by the constant current charging method,
The charging controller changes the first history power storage amount based on the increase rate of the power storage amount when the power storage amount increases and reaches the reference power storage amount, and when the power storage amount decreases and reaches the reference power storage amount, the power storage amount The solar power generation system, characterized in that the variable amount of the second hysteresis based on the reduction rate of the. The solar power generation system according to claim 1, wherein the charge controller decreases the first history power storage amount when the increase speed of the power storage amount is faster than a reference increase speed. The photovoltaic power generation system according to claim 2, wherein the amount of reduction of the first hysteresis amount is proportional to a value obtained by subtracting the reference increase rate from the increase rate of the power storage amount. The solar power generation system according to claim 1, wherein the charge controller increases the first history power storage amount when the increase speed of the power storage amount is slower than a reference increase speed. The photovoltaic power generation system according to claim 4, wherein the amount of increase in the first hysteresis amount is proportional to a value obtained by subtracting the increase rate of the amount of power storage from the reference increase rate. The solar power generation system according to claim 1, wherein the charging controller decreases the second hysteresis amount when the reduction rate of the power storage amount is faster than a reference reduction rate. The photovoltaic power generation system according to claim 6, wherein the amount of reduction of the second history power storage amount is proportional to a value obtained by subtracting the reference reduction speed from the reduction speed of the power storage amount. The solar power generation system of claim 1, wherein the charging controller increases the second hysteresis amount when the reduction rate of the power storage amount is slower than a reference reduction rate. The photovoltaic power generation system according to claim 8, wherein the amount of increase in the second hysteresis power is proportional to a value obtained by subtracting the reduction speed of the power storage amount from the reference reduction speed.

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