JP5012555B2 - Power supply for mobile vehicles - Google Patents

Description

  The present invention relates to a mobile vehicle power supply device, and more particularly to a mobile vehicle power supply device using a battery such as a forklift as a power source.

A rechargeable battery such as a lead battery is mounted on a mobile vehicle powered by a battery such as a battery forklift, and regenerative energy from a traveling motor is stored in the secondary battery. However, existing batteries have poor charging efficiency with a rapidly increasing current during regeneration, and have an adverse effect on battery life.
For this reason, Patent Documents 1 to 3 are known as means for extending the battery life.
In these, a capacitor and a battery are connected in parallel, the regenerative power is charged in the capacitor to extend the battery life, and the regenerative power is effectively used.

In general, as a method for extending the battery life, a regenerative current blocking die auto is connected between the battery and the DC circuit of the power converter (inverter or chopper), and the regenerative energy is stored in the capacitor, as shown in FIG. As shown, a chopper Ch is connected to a DC circuit, and a battery current is controlled by the chopper to store regenerative energy in the electric double layer capacitor C.
JP-A-6-270695 JP 2002-315109 A Japanese Patent Laid-Open No. 2003-219566

In the former method, the regenerative current that flows through the battery is blocked by the diode, because the current flows through the diode when the moving body is powered, and loss due to the diode occurs. Therefore, if the resistance of the capacitor is large, the peak value of the battery current does not decrease. The smaller the battery current peak value, the longer the battery life, which is contrary to the extension of the battery life.
Normally, when an inverter is used as the power conversion unit, the allowable voltage of the inverter has no margin with respect to the battery voltage, and thus it is necessary to increase the capacity of the capacitor.
Energy stored = 0.5 * capacity * (capacitor maximum voltage ² -capacitor minimum voltage ² )
Thus, the larger the voltage difference, the more energy can be stored.

  On the other hand, in the case of the latter chopper method shown in FIG. 4, the capacitance of the capacitor can be reduced by using the capacitor at a high voltage. However, the resistance is increased and the loss is increased by reducing the parallel number of capacitors.

  In Patent Document 1, when the configurations of FIGS. 2 and 3 are adopted, when regenerative power from the motor is charged to the capacitor, if the regenerative energy is large or regenerative braking continues for a long time, the capacitor voltage increases greatly. Therefore, there is a risk that the upper limit of the rated value of the inverter or capacitor will be damaged and the AC motor may be damaged.

  In Patent Document 2, since the capacitor and the battery are connected in parallel, basically, the voltage fluctuation of the battery is small and the capacitor does not exceed the rated upper limit voltage. However, since the capacitor and the battery are connected in parallel, the rate of regenerative energy stored in the capacitor is inversely proportional to the capacitor and battery resistance, and the stored energy decreases when the capacitor resistance is large. . In addition, it is necessary to set the time constants T1 and T2 of the capacitor and the battery including the wiring inductance based on the maximum overcurrent. In-vehicle power supplies are difficult to use due to restrictions on circuit layout.

  In Patent Document 3, as in Patent Document 1, when a capacitor is charged with regenerative power, the increase in the capacitor voltage increases and exceeds the rated upper limit of the inverter and the capacitor, resulting in damage to the AC motor. I have a fear.

  An object of the present invention is to provide a power supply device for a mobile vehicle that can reduce the capacity and reduce the size of an expensive electric double layer capacitor.

Claim 1 of the present invention is an inverter connected to a battery and capable of regenerative operation, a motor connected via the inverter, a chopper connected to a DC circuit of the battery, having a reactor and a switching element, and the chopper In a mobile vehicle power supply device comprising an electric double layer capacitor connected to
A differentiating unit for detecting the battery voltage and differentiating the detected voltage; a current component calculating unit for executing a multiplication of a differential signal by the differentiating unit and a coefficient for realizing a desired capacitor current for the electric double layer capacitor; A difference signal between the current command output from the current component calculation unit and the detected current flowing through the chopper is obtained, and a gate signal corresponding to the difference signal is generated to control the chopper. .

According to a second aspect of the present invention, a plurality of switching elements of the chopper are used for charging and discharging, the positive / negative of the current command I _L ^* output from the current component calculation unit is determined, and when I _L ^* ≧ 0, the electric double layer Only the switching element for charging the capacitor is controlled to be switched, and when I _L ^* <0, only the switching element for discharging the electric double layer capacitor is controlled to be switched.

  As described above, according to the present invention, since a large-capacity capacitor is equivalently connected by a small-capacity electric double layer capacitor C, an expensive electric double-layer capacitor can be reduced in size and cost. It is also advantageous. In addition, since the relationship between current and voltage can be set as an ideal capacitor, the internal resistance of the capacitor can be equivalently reduced to 0, and current does not easily flow to the electric double layer capacitor as in the past. Also disappear. Further, switching loss can be further suppressed by performing switching control on only one side of the two switching elements based on whether the calculated current command value of the chopper is positive or negative.

In the present invention, a value obtained by multiplying the differential value of the battery voltage V _{B by} the capacity Cs is set as the calculation setting I _L ^* . As a result, the chopper current I _L is caused to perform an operation equivalent to a capacitor current when an electric double layer capacitor having a capacity Cs and an internal resistance 0 is directly connected in parallel to the battery. Hereinafter, it explains in full detail based on an Example.

FIG. 1 is a block diagram of a chopper control circuit showing a first embodiment of the present invention. In the main circuit of the power supply apparatus, an inverter INV capable of regenerative operation is connected to the battery B as in FIG. 4, and the motor M is controlled via this inverter. Ch is a chopper, which has a reactor L and switching elements S1 and S2, and an electric double layer capacitor C is connected to the chopper Ch to form a regenerative current storage unit RA. Reference numeral 1 denotes a voltage detector for detecting a battery voltage, 2 denotes a low-pass filter, and the battery voltage V _B detected by the detector 1 is subjected to noise removal processing by the low-pass filter 2 and then differentiated by the differentiating means 3. The Reference numeral 4 denotes a current command calculation unit, and in order to realize an ideal large-capacity capacitor current inflow to the electric double layer capacitor C, the current command calculation unit 4 performs multiplication of the differential value and the capacitance Cs.

  The capacitance Cs is a capacitor capacitance for realizing the inflow of a large capacitance capacitor current ideal for the electric double layer capacitor C, and is arbitrarily set. Reference numeral 5 denotes a subtracting unit that calculates a difference between the output of the current command calculating unit 4 and the current flowing into the regenerative current accumulating unit RA detected by the current detector 6. The difference signal is input to the current control unit 7 as a current command value that flows into the regenerative current value accumulation unit RA, and the current control unit 7 executes a PI calculation according to the current command value, generates a gate signal by PWM, and generates a chopper Ch. Perform on / off control.

In the present invention, the chopper current I _L detected by the current detector 6 is used as a detection value applied to the current control. Here, it is assumed that the electric double layer capacitor C has zero internal resistance and an ideal large-capacity capacitor Cs value (> C), and the electric double-layer capacitor having the large-capacitance capacitor Cs directly It is assumed that the battery B is connected in parallel. The current I _S to the electric double layer capacitor at that time is calculated, and this is used as the current command I _L ^* of the chopper Ch. Thus, the electric double layer capacitor C having the capacity Cs is obtained, and the one having this capacity Cs is obtained. An operation equivalent to that connected directly in parallel to the battery B is realized.

The current I _S flowing through the ideal electric double layer capacitor having the capacity Cs may be obtained by multiplying the differential component of the battery voltage V _{B by} the capacity Cs as shown in the equation (1). Execute.

I _L ^* = I _S = Cs · d / dt (V _B ) (1)
FIG. 2 shows a simulation result when power running and regeneration are performed alternately. It can be seen that the peak value of the battery current during power running is effectively suppressed and the current is flat.

  According to this embodiment, since the electric double layer capacitor C has a small capacitance and an equivalent large capacitance is connected, it is possible to reduce the size of the expensive electric double layer capacitor, which is cost effective. It is also advantageous. In addition, since the relationship between current and voltage can be set as an ideal capacitor as shown in equation (1), the internal resistance of the capacitor can be equivalently set to 0. Current does not become difficult to flow.

FIG. 3 shows the second embodiment. The difference from the first embodiment shown in FIG. 1 is that a gate signal generator 8 is provided on the output side of the current controller 7, It is the same.
The gate signal creation unit 8 includes a determination unit 81, a first gate circuit 82, and a second gate circuit 83. In this embodiment, in order to reduce the switching loss of the chopper Ch, the switching elements S1 and S2 are not alternately switched. Only the switching element on one side according to the charging / discharging state of the electric double layer capacitor C is used. On-off control is performed. For this purpose, the calculated current command I _L ^* for the chopper calculated by the current command calculation unit 4 is input to the determination unit 81 to determine whether or not it is greater than zero. As a result, when the current command I _L ^* ≧ 0, a signal is output to the first gate circuit 82, only the switching element S2 is turned on, and the element S1 maintains the off state. Further, when the current command I _L ^* ≦ 0, the determination unit 81 outputs a signal to the second gate circuit 83, turns on only the switching element S1, and keeps the element S2 in the off state.

The chopper Ch operates as a step-up chopper when the electric double layer capacitor C is charged, and discharges using a potential difference (= V _EDLC −V _B ) at the time of discharging. Therefore, the operating condition of this control is (battery voltage V _B ) <(Electric double layer capacitor voltage V _EDLC ).

  According to this embodiment, in the chopper control circuit, in order to reduce the switching loss by the two switching elements, the switching control of only one side of the two switching elements is performed based on the calculated current command value. As a result, the switching loss can be further suppressed as compared with the first embodiment.

The block diagram which shows the Example of this invention. Simulation result diagram. The block diagram which shows the other Example of this invention. The main circuit block diagram of the power supply device for mobile vehicles.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Voltage detector 2 ... Low pass filter 3 ... Differentiation means 4 ... Current command calculating part 5 ... Subtraction part 6 ... Current detection part 7 ... Current control part 8 ... Gate signal preparation part 81 ... Determination part

Claims (2)

An inverter connected to the battery and capable of regenerative operation, a motor connected via the inverter, a chopper connected in parallel with the battery and having a reactor and a switching element, and an electric double layer capacitor connected to the chopper In a moving vehicle power supply device,
A differentiating means for detecting the battery voltage and differentiating the detected voltage; a current command calculation unit for executing a multiplication of a differential signal by the differentiating means and a coefficient for realizing a desired capacitor current for the electric double layer capacitor; A mobile vehicle characterized in that a difference signal between a current command output by a current command calculation unit and a detected current flowing through the chopper is obtained, and a gate signal corresponding to the difference signal is generated to control the chopper. Power supply. A plurality of switching elements of the chopper are used for charging and discharging, and whether the current command I _L ^* output from the current command calculation unit is determined, and when I _L ^* ≧ 0, only the switching element for charging the electric double layer capacitor The power supply device for a mobile vehicle according to claim 1, wherein switching control is performed for only the discharge switching element of the electric double layer capacitor when I _L ^* <0.

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