JP2553327B2 - Solar power generator - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a charging control method for a storage battery in a solar power generation device that uses a solar cell, and particularly direct current from the solar cell to the storage battery via a DC / DC converter. The present invention relates to a charging control method in a photovoltaic power generation device configured to charge.

[Prior art]

FIG. 5 is a block diagram showing an outline of the solar power generation device. The solar power generation device includes a solar cell 1, a storage battery 3 that charges the direct current generated by the solar cell 1, and a switch 2 that turns on and off the current from the solar cell 1. Also,
The storage battery 3 is connected to the load 4.

In the solar power generation device configured as described above, the conventional method of charging the storage battery 3 is to turn on the switch 2 when the terminal voltage of the storage battery 3 is low and charge the storage battery 3 with direct current generated by the solar battery 1. When the storage battery 3 reaches full charge, the switch 2 is turned off to prevent the storage battery 3 from being overcharged, and charging of the storage battery 3 is stopped.

[Problems to be solved by the invention]

However, as described above, according to the conventional charging method, when the storage battery 3 is fully charged and the switch 2 is opened, the solar cell 1
There is a problem that the electric power generated in the above is not used at all. In addition, there is a problem in that the voltage fluctuation is large, for example, the terminal voltage of the storage battery 3 fluctuates depending on the magnitude of the current flowing through the load 4 only when the switch 2 is turned on and off.

The present invention has been made in view of the above points, and eliminates the above problems and provides a charging control method in a solar power generation device that can effectively use the electric power generated by a solar cell and has a stable voltage. Especially.

[Means for solving problems]

In order to solve the above problems, the present invention provides a solar cell and a storage battery, a DC that controls the output voltage of the solar cell to a predetermined voltage.
Connected via a DC / DC converter, the maximum power point tracking means that outputs a signal to output to the DC / DC converter at the voltage of the maximum power point of the solar cell, the terminal voltage of the storage battery, and the maximum power point And a switching control means for controlling the signal output from the tracking means to the DC / DC converter. When the switching control means detects a voltage lower than the full charge state, the maximum output point tracking means changes the DC / DC converter. When the switching control means detects a fully charged voltage, the maximum output point tracking means cuts off the signal output to the DC / DC converter.

[Action]

With the above configuration, while the terminal voltage of the storage battery is sufficiently low, the solar battery operates at the maximum output power point because the maximum power point tracking device controls the DC / DC converter to charge the storage battery. When the storage battery approaches the fully charged state, the current control device is switched to the control so that the storage battery can be prevented from being overcharged and the electric power generated by the solar cell can be effectively used within the range where the storage battery does not become overcharged. it can.

〔Example〕

 An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing a system configuration of a photovoltaic power generation device using a charging control system according to the present invention. In the same figure, the parts given the same reference numerals as in FIG. 2 indicate the same or corresponding parts. DC / DC 5 is a DC voltage generated by the solar cell 1 which is stepped up or down and supplied to the storage battery 3 and the load 4.
The converter 6 is a maximum power point tracking means (hereinafter, maximum power point tracking control device) for controlling the output voltage and the output current so that the output of the solar cell 1 is maximized, as will be described later in detail, K
Is a switching control means for switching the operation of the maximum power point tracking control device 6, whereby the maximum output point tracking control device 6 detects when the terminal voltage of the storage battery 3 is lower than the reference voltage in the fully charged state. DC / DC at maximum power point voltage
When the terminal voltage of the storage battery 3 reaches the voltage in the fully charged state, the converter 5 is made to output, and the signal output from the maximum output point tracking control device 6 to the DC / DC converter 5 is cut off, and at the same time, the DC / DC The output from the converter 5 is supplied to the storage battery 3. Here, 7 which constitutes the switching control means K detects the terminal voltage of the storage battery 3 and adjusts the output voltage of the DC / DC converter 5 so that the storage battery 3 is not overcharged and controls the charging current. , 8 is the DC
The changeover switch for switching the control of the / DC converter 5 from the maximum power point tracking control device 6 to the current control device 7 or from the current control device 7 to the maximum power point tracking control device 6, 9 is the charging state from the terminal voltage of the storage battery 3 Is detected and the changeover switch 8 is changed over to the maximum power point tracking control device 6 side or the current control device 7 side.

By the way, the output voltage-current characteristic of the solar cell 1 is as shown in FIG. As shown in the figure, the light quantity LQ ₁ , ~
In order to make the most effective use of the electric power generated by the solar cell 1 in which the output voltage V and the output current I are changed by the LQ ₄ , the output voltage V and the output current I are set to the maximum power points P _{1 to} P ₄ . Need to maintain. The maximum power point tracking control device 6 in FIG.
This is a device that maintains the output of the solar cell 1 at the maximum power points P _{1 to} P ₄ . That is, from the output current I and the output voltage V detected by the current sensor 10, the output voltage V and the output current I of the solar cell 1 are calculated.
The output of the DC / DC converter 5 is controlled so that is always on the dotted line A in FIG.

In the photovoltaic power generation device configured as shown in FIG. 1, when the terminal voltage V _B of the storage battery 3 is smaller than the terminal voltage when fully charged, the changeover control circuit 9 causes the changeover switch 8 to switch the maximum power point tracking control device. Defeat to side 6. Thereby, the maximum power point tracking control device 6 controls the DC / DC converter 5, and the solar cell 1 operates at the maximum power point (see P _{1 to} P _{4 in} FIG. 2) regardless of the state of charge of the storage battery 3. The output voltage and output current are controlled as described above. When the terminal voltage V _B of the storage battery 3 rises and approaches a fully charged state, the changeover control circuit 9 turns the changeover switch 8 to the current control device 7 side. As a result, the current control device 7 prevents the storage battery 3 from being overcharged regardless of whether or not the output of the solar cell 1 is at the maximum power point according to the terminal voltage V _B of the storage battery 3. The output of 5 is adjusted to control the charging current. When the storage battery 3 is no longer fully charged due to an increase in the load current supplied to the load 4, the cutover control circuit 9 again turns the changeover switch 8 to the maximum power point tracking control device 6 side, and the maximum power point tracking is performed. Control device 6
In order to maintain the output of solar cell 1 at the maximum power point, DC
/ DC converter 5 is controlled.

Although various types of maximum power point tracking control device 6 are conceivable, for example, the technique disclosed in Japanese Patent Application Laid-Open No. 58-69469 may be used. FIG. 3 is a block diagram showing an example in which the technique disclosed in the above document is used in the solar power generation system of FIG.

The relationship between the output current of the solar cell 1 and the electric power is shown in FIG. That is, the power P increases as the output current I increases, and decreases when the maximum power point Pmax is exceeded. Therefore, the maximum power point tracking control device 6 may maintain the output of the solar cell 1 at this maximum power point.

In FIG. 3, the multiplier 61 indicates the output voltage V of the solar cell 1.
And the output current I as input signals, and the product
Output power P = V × I is calculated and output. The differentiating circuit 62 time-differentiates the electric power P to calculate dP / dt. Comparator 63
Determines whether the differential output dP / dt is positive or negative, and dP / dt
Outputs H (high) level when> 0, L when dP / dt <0
Outputs (low) level. In the ramp function circuit 64, the output ramps up when the potential at point A is positive, and the ramp ramps down when the potential at line A is negative. Bidirectional Zener diode connected between the output terminals of this ramp function circuit 64
65 is for clamping the top and bottom. Inversion circuit 66
DC / DC when the output of the ramp function circuit 64 is increasing
The output voltage of the converter 5 is decreased, and conversely, when the output of the ramp function circuit 64 is decreasing, the output voltage of the DC / DC converter 5 is increased. The exclusive OR circuit 68 outputs a positive voltage when the two inputs B and C are both negative and outputs the two inputs B and C.
When one of them is positive and the other is negative, it outputs a negative voltage.
The bistable multi-circuit 67 stores the voltage of the input A,
When the control terminal D is at H level, the input A is transmitted to the output B. The OR circuit 69 outputs the H level when either the output C of the comparator 63 or the output of the clock pulse CP is the H level. The clock pulse generator 70 has, for example, 1 second per second.
The clock pulse CP is output at the output cycle.

In the solar power generation device shown in FIG. 3, when the operating point of the solar cell 1 is below the maximum output point Pmax and the output voltage of the DC / DC converter 5 is increasing as shown in FIG. When the A point is at the L level and the C point is at the H level, and the operating point of the solar cell 1 is the maximum output point pm as shown in FIG.
When the output voltage of the DC / DC converter 5 is not less than ax and the output voltage of the DC / DC converter 5 is decreasing, that is, when the point A is at the L level and the point C is at the H level, the solar cell 1 will continue if the state of the shade is continued.
The operating point of approaches the maximum output point Pmax. Further, as shown in FIG. 4, when the operating point of the solar cell 1 is less than or equal to the maximum output point Pmax and the output voltage of the DC / DC converter 5 is decreasing, that is, the A point is at the L level and the C point is at the L level. At the level and as shown in FIG. 4, the operating point of the solar cell 1 is the maximum output point.
When the output voltage of the DC / DC converter 5 is higher than Pmax and the output voltage of the DC / DC converter 5 is increasing, that is, when the point A is at the H level and the point C is at the L level, both are far from the operating point of the solar cell 1. By inverting the output of the exclusive OR circuit 68, the operating point changes so as to approach the maximum output point Pmax. As described above, the maximum power point tracking control device 6 is operated at the maximum output point Pmax of the solar cell 1 regardless of the state of charge of the storage battery 3.

The details of the operation of the maximum power point tracking control device 6 are disclosed in JP-A-58-69469, and will not be described.

When the solar cell 1 is operated at the maximum output point Pmax as described above and the storage battery 3 approaches full charge, the changeover control circuit 9 tilts the changeover switch 8 to the current control device 7 side as described above, and the current control device 7 The output voltage of the DC / DC converter 5 is adjusted to suppress the charging current so that the storage battery 3 is not overcharged.

It should be noted that in the above embodiment, the maximum power point tracking control device 6 may of course be a technique described in, for example, Japanese Patent Application Laid-Open No. 56-132174, in addition to the above.

〔The invention's effect〕

As described above, according to the present invention, when the terminal voltage of the storage battery is lower than the reference voltage, the voltage controlled by the maximum output point tracking means is supplied to the storage battery. Power can be used effectively. Further, when the storage battery reaches the reference voltage (fully charged state), the DC / DC converter supplies a predetermined voltage to the storage battery, so that the storage battery is not only prevented from becoming overcharged, Since the voltage fluctuation of the storage battery can be made smaller than before, it is possible to expect an excellent effect that the life of the storage battery is extended and the safety against load is secured.

[Brief description of drawings]

FIG. 1 is a block diagram showing a system configuration of a solar power generation device using a charge control system according to the present invention, FIG. 2 is a diagram showing output voltage-current characteristics of a solar cell, and FIG. 3 is JP-A-58-.
FIG. 4 is a block diagram showing an example in which the technology disclosed in Japanese Patent Publication No. 69469 is used in the photovoltaic power generation device of FIG. 1, FIG. 4 is a diagram showing power change with respect to output current of a solar cell, and FIG. It is a block diagram which shows the outline | summary of an apparatus. In the figure, 1 ... solar battery, 3 ... storage battery, 4 ... load, 5
...... DC / DC converter, 6 ... Maximum power point tracking control device, 7 ... Current control device, 8 ... Changeover switch, 9 ...
Switching control circuit, 10 ... Current sensor.

Claims (1)

(57) [Claims] 1. A solar cell and a storage battery are connected via a DC / DC converter that controls the output voltage of the solar cell to a predetermined voltage, and the DC voltage is the maximum power point of the solar cell.
/ A maximum power point tracking means for outputting a signal to be output to the DC converter, and a switching control means for detecting the terminal voltage of the storage battery and controlling the signal output from the maximum power point tracking means to the DC / DC converter. When the switching control means detects a voltage lower than a full charge state, the maximum output point tracking means outputs a signal to the DC / DC converter, and the switching control means outputs a voltage in a full charge state. Is detected from the maximum output point tracking means,
A solar power generation device characterized in that the signal output to the DC / DC converter is cut off.