KR101886488B1 - Method for controllingr electric generating system using solar cell - Google Patents

Abstract

The present invention relates to a power generation control method of a solar cell system in which a time point at which a heating value reaches a maximum according to a shadow ratio can be determined as a change in resistance value of a short-circuit current condition in shadow diagnosis of a part of a solar cell module.
That is, according to the present invention, in a solar cell module in which each battery cell is integrally connected in series without a bypass diode, a shadow (shade) ratio at which a heat generation amount is maximized is determined as a resistance value under a short- (PVPT) control for power generation control of the solar cell module is changed or switched off when the power consumption of the solar cell module is lower than the reference value, And to provide a method.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for controlling a solar cell,

The present invention relates to a method for controlling power generation of a solar cell system, and more particularly, to a method for controlling power generation of a solar cell system in which when a shadow of a part of a solar cell module is shadowed, And more particularly, to a power generation control method of a solar cell system.

In order to maximize the power generation efficiency of the solar cell module, it is preferable that the direct sunlight of the sun is always installed on the front surface of the solar cell module. However, the solar cell module installation angle, Shadows (shadows) can be applied to part or all of the solar cell module due to external factors.

If at least one of the plurality of battery cells (strips) constituting the solar cell module is blocked due to shadows or foreign substances, the current of the corresponding battery cell is reduced to fail to produce electric power, Flow, which results in power loss of the entire solar cell module.

In addition, when the current of the shaded battery cell decreases, heat is generated, and the heat generated at this time causes secondary damage to the solar cell module.

In order to prevent such thermal damage, as a means for smoothly flowing the current of the remaining normal cells, a bypass diode is provided in parallel in the cell serial node for every predetermined number of cells.

When each cell of the solar cell module is connected in series, a bypass diode may be inserted between cells to perform thermal management. However, in the case of a solar cell module connected in series, it is difficult to insert a bypass diode, Which can lead to thermal losses.

More specifically, in the case of a solar cell module (solar cell panel) in which each battery cell is integrally connected in series without the bypass diode, if a shadow exists in a part of all the cells, Although power generation can be utilized without the module being switched off, if the heating value is maximum at a certain rate and sustained, heat loss and cell damage may be caused.

For example, damage to the battery cell itself or destruction of the junction portion of the solar cell panel or the conductive soldering portion of each device may occur.

In the solar cell module in which each battery cell is integrally connected in series without the bypass diode as described above, the shadow (shadow) ratio at which the heat generation amount is maximized is determined as the resistance value under the short-circuit current condition. When the resistance value is lower than the reference value, the MPPT (Maximum Power Point Tracking) control for controlling the power generation of the solar cell module is changed or switched off to prevent generation of heat due to heat generation and cell damage And a control method.

According to an aspect of the present invention, there is provided a solar cell module comprising: i) measuring a resistance value change when a plurality of battery cells are integrated and a solar cell module connected in series is driven to generate electricity; Ii) determining whether the measured resistance value Rsc is less than a reference value A, which is an arbitrary set value larger than the resistance value in the short-circuit current condition, in a shaded (shaded) condition in which the calorific value becomes the maximum; And iii) when the measured resistance value Rsc is smaller than the reference value A, changing the MPPT control or performing switch-off control; And controlling the power generation of the solar cell system.

Preferably, the step of determining whether the duration time when the measured resistance value Rsc is smaller than the reference value A before the step iii) is greater than the reference time B is further performed, And the step (iii) is performed if the time is larger than the time (B).

More preferably, after step (iii), the step of informing the outside that the MPPT control is changed or the switch-off control is performed at a shadow ratio at which the heating value is maximized is further performed.

Preferably, the reference value A is determined depending on the number of cells of the solar cell module.

If it is determined that the output value of the solar cell module has decreased to be equal to or greater than the reference ratio (C%) after determining whether the output value of the solar cell module has decreased to or above the reference ratio (C%) of the rated output during the process of measuring the resistance value (Rsc) And when the output value of the solar cell module increases as it is, the MPPT control is performed as it is.

Preferably, the changing of the MPPT control is performed to maintain a higher voltage than a maximum power point so as to reduce the amount of heat generated while lowering the current.

Through the above-mentioned means for solving the problems, the present invention provides the following effects.

First, in the solar cell module in which the battery cells are connected in series without the bypass diode, the shadow (shade) ratio at which the heat generation amount is maximized can be grasped accurately.

That is, the shadow (shade) ratio at which the amount of heat generation is maximized can be accurately determined as the resistance value in the short-circuit current condition.

Second, the maximum power point tracking (MPPT) control for power generation control of the solar cell module is changed or switched off at a shadow (shade) ratio at which the heat value is maximized, thereby preventing heat loss and cell damage.

1 and 2 are graphs showing a current-voltage curve according to a shadow ratio after a solar cell module is fabricated in a total of 10 strips, that is, a total of 10 cells are integrally connected in series without a bypass diode,
3 is a flowchart showing a power generation control method of a solar cell system according to the present invention,
FIG. 4 and FIG. 5 are graphs showing an example of measurement of resistance value of a solar cell module according to an embodiment of the present invention by shadow condition. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First, in order to facilitate the understanding of the present invention, the reason why the shadow (shade) ratio at which the heat generation amount of the solar cell module becomes maximum can be determined as the resistance value under the short-circuit current condition will be described.

FIGS. 1 and 2 are cross-sectional views illustrating a method of fabricating a solar cell module according to an embodiment of the present invention. Referring to FIG. 1 and FIG. 2, a total of 10 strips, Voltage curve.

As shown in FIG. 1, when no shadow is formed on the entire solar cell module (NO SHADE), when one cell out of 10 cells is shadowed (1 STRIP SHADE) (3 STRIP SHADE) shows that the calorific value (loss amount) becomes the maximum when three cells are shadowed, compared to 2 STRIP SHADE.

As shown in FIG. 2, the shadow (shading) condition in which the heat generation is maximized is measured as the resistance value (Rsc = | dV / dI |) under the short-circuit current condition by measuring the resistance value change during the power generation operation of the solar cell module .

That is, the shadow (shadow) condition in which the heat is maximum is 3 STRIP SHADE when three cells out of 10 cells are shaded, and the measured resistance value Rsc is the resistance value in the short- Rsc = | dV / dI | sc, the slope reciprocal in the graph of Fig. 2).

As a result, the shadow (shading) condition at which the heat is maximized can be judged when the resistance value (Rsc = | dV / dI | sc) at the short-circuit current condition is the smallest.

The short circuit current is the same in the normal module current and the shade condition in the shade condition in which the maximum heat generation is the maximum, and if the power generation drive of the solar cell module continues under this condition, the cell damage due to the excessive heat generation may be caused.

Therefore, the present invention attempts to determine the shadow (shade) ratio at which the heating value becomes maximum as the resistance value under the short-circuit current condition, and the measured resistance value Rsc is smaller than the reference value A The maximum power point tracking (MPPT) control for controlling the power generation of the solar cell module is changed or switched off so as to prevent loss due to heat generation and damage to the cell There is a point to the point.

FIG. 3 is a flowchart illustrating a power generation control method of a solar cell system according to the present invention.

First, a change in resistance value is measured when a solar cell module connected in series with a plurality of battery cells integrally connected without a bypass diode is driven for power generation (S101).

Subsequently, it is determined whether the measured resistance value Rsc is smaller than a reference value (A, an arbitrary set value larger than the resistance value in the short-circuit current condition) (S102).

If the measured resistance value Rsc is smaller than the reference value A, MPPT control for solar cell power generation or switch off control for turning off solar cell power generation is performed (S104).

For reference, MPPT (Maximum Power Point Tracking) is the control of the maximum power point control so that the solar cell module can output the maximum power.

Therefore, changing the MPPT control means that the high voltage is maintained at a higher shade (shade) ratio at which the calorific power is maximized than the maximum power point. At the same time as the MPPT control is changed or switched off, It is possible to reduce the heat generation amount, thereby easily preventing damage due to heat generation and cell damage.

On the other hand, when the measured resistance value Rsc is less than the reference value A, the temperature of the solar cell module due to heat generation increases, whereas when the measured resistance value Rsc is smaller than the reference value A The resistance value Rsc may increase again from the reference value A and the amount of heat generated may decrease after the duration.

If the measured resistance value Rsc is smaller than the reference value A, it is determined whether or not the duration is greater than the reference time B (S103). If the measured resistance value Rsc is greater than the reference time A, .

When the MPPT control is changed or the switch-off control is performed, the external monitoring system of the solar cell system is notified of the shading (S105).

That is, it is noticed that the MPPT control is changed or the switch-off control is performed in the shadow (shade) ratio at which the heating value becomes the maximum.

On the other hand, when the resistance value Rsc is measured, it is determined whether the output value of the solar cell module has decreased to a reference ratio (C%) of the rated output or more. When the output value of the solar cell module again increases to the original value, the MPPT control is performed again as it is, and the power generation drive of the solar cell module can be more efficiently managed.

Hereinafter, the present invention will be described in more detail through an embodiment.

Example

A total of 10 strips, a total of 10 cells, were fabricated in series with the bypass diode without a diode.

The generated solar cell module was driven to generate electricity, and the resistance value (Rsc = | dV / dI | sc) was measured from the output current and voltage according to the driving. FIGS. 4 and 5 show the results - Voltage curve graph.

As shown in FIG. 4, the resistance value (Rsc) is measured to be about 800Ω when no shadow is formed on the entire solar cell module (NO SHADE) and when 1 cell is shadowed (1 STRIP SHADE) .

On the other hand, as shown in FIG. 5, the resistance value (Rsc) measured at 3 STRIP SHADE when three cells out of 10 constituting the solar cell module is shaded was measured as about 83Ω, As the resistance value (Rsc = | dV / dI | sc), it was the smallest measured value compared to the other shadow conditions. As a result, the shadow (shadow) (3 STRIP SHADE).

Therefore, in order to prevent cell damage due to heat generation in a shadow condition in which heat generation is maximized, the reference value A, which is compared with the resistance value Rsc measured as above, can be set to about 100?.

For reference, the reference value A is an arbitrary set value that is larger than the resistance value in the short-circuit current condition when the heating value is maximum (shadow) condition as described above. .

Therefore, if the measured resistance value Rsc is smaller than the reference value A, MPPT control for solar cell power generation is changed, or switch off control for turning off the solar cell power generation is performed, Cell damage and the like can be easily prevented.

Claims (7)

I) measuring a change in resistance value when a plurality of battery cells are integrated and a solar cell module connected in series is driven to generate electricity;
Ii) determining whether the measured resistance value Rsc is less than a reference value A, which is an arbitrary set value larger than the resistance value in the short-circuit current condition, in a shaded (shaded) condition in which the calorific value becomes the maximum;
Iii) when the measured resistance value Rsc is smaller than the reference value A, changing the MPPT control or performing switch-off control;
, ≪ / RTI &
The step of determining whether the duration when the measured resistance value Rsc is smaller than the reference value A is greater than the reference time B before the step iii) ), The step (iii) is carried out.
delete The method according to claim 1,
After the step iii)
Further comprising the step of informing the outside that the MPPT control is changed or that the switch-off control is performed at a shadow ratio at which the heating value is maximized.
The method according to claim 1,
Wherein the reference value (A) is determined according to the number of cells of the solar cell module.
The method according to claim 1,
If it is determined that the output value of the solar cell module has decreased to be equal to or greater than the reference ratio (C%) of the rated output during the process of measuring the resistance value (Rsc), the step (iii) Wherein the step of controlling the power generation of the solar cell system comprises the steps of:
The method of claim 5,
And when the output value of the solar cell module increases as it is, the MPPT control is performed again as it is.
The method according to claim 1,
Wherein the step of changing the MPPT control is to maintain a higher voltage than a maximum power point so as to reduce the amount of heat generated while lowering the current.

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