FI88232C - A method for controlling the output current of a DC / DC converter and its use - Google Patents

Description

88232 Adjustment method for adjusting the output current of a DC / DC converter and its use For adjusting the output current of the DC / DC converter from 5 to DC / DC omcandlare och dess användning

The invention relates to a method for adjusting the output current of a DC / DC converter, in which method an energy generating device is adapted to supply energy to a device storing it via a converter.

The control method according to the invention can be applied e.g. in such a way that the converter is fed e.g. by a solar panel and the load is a battery. In this case, a current corresponding to the maximum power of the solar panel is supplied to the 15 batteries.

A solution is known from the prior art in which current and voltage are measured from a solar panel and the maximum power is calculated by a microcomputer or an analog multiplier.

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A control method in which a separate _ is measured is also known from the prior art. the output current of the converter and is used to form a control system. . control signal for the system.

25 A disadvantage of the solutions known from the prior art is that the steel solutions are relatively complex and thus expensive.

It is an object of the invention to provide an improvement over the currently known control methods.

It is a detailed object of the invention to provide a control method which makes it possible to adjust the energy generating device and the energy storage device so that the energy generating device operates as close as possible to its maximum power point.

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Yet another detailed object of the invention is to provide a control method which is as simple as possible in terms of equipment solution and thus very cheap in terms of purchase price.

The objects of the invention are achieved by a control method, which is mainly characterized in that the control method measures the internal current of the transducer by means of a measuring circuit, directs the controlling the gate circuit so that the polarity of the output of the gate circuit is reversed if the current derivative is negative at the end of the delay period.

The solution according to the invention achieves clear advantages over traditional solutions. The control method according to the invention does not require cumbersome and expensive output current measurement. The solution according to the invention is simpler compared to previously used microprocessors or analog coefficients. The simple and inexpensive main circuit (power electronics) of the solution according to the invention also enables good efficiency.

The applications of the solution according to the invention are e.g. charging the battery using a solar cell, a wind generator, a burn-25 cell or a thermoelectric generator as an energy source.

The invention thus provides a new solution based on the fact that the voltage of the battery in energy storage can be assumed to be constant in the short term. Second, instead of measuring the output current, a measurement of the internal current of the 30 transducers is used, resulting in a simpler power stage topology and measurement. In this case, the battery receives maximum power when the current supplied to the battery is at its maximum. The search for maximum power, i.e. the measurement and multiplication of two quantities, thus changes in the solution according to the invention for measuring one quantity, i.e. for measuring the current inside the converter.

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The invention will be explained in detail with reference to some preferred embodiments of the invention shown in Figures 1-7 of the accompanying drawings, to which, however, the invention is not intended to be exclusively limited.

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Figure 1 shows a control method according to the invention in a block diagram.

Figure 2 shows graphically the signals shown in Figure 1 as a function of time.

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Figure 3 shows the topology of the main circuit used in the control method according to the invention and the current measurement as a circuit connection.

Figure 4 shows a preferred embodiment of an indirect current measuring circuit used in the control method according to the invention in principle.

Fig. 5 shows the current and voltage signals shown in Fig. 4 with an open current.

20 *: ··· Figure 6 shows the current and voltage signals shown in Figure 4 at a constant current.

Figure 7 shows a schematic circuit in which a solar panel, a wind generator, a fuel cell or a thermoelectric generator charges the battery via a converter.

The control method according to the invention is illustrated in Figures 1-3.

The conversion ratio of the converter 11 is continuously controlled by the control signal b obtained from the gate circuit 12. The direction of the change in the conversion ratio is proportional to the polarity of the control signal b. At the same time, the internal current Ia of the converter 11 is measured according to Fig. 3. From this current, an estimate of the output current Iout of the converter 11 is formed by the measuring element 35 13. The obtained signal I is applied to the reference element 14 both directly as the instantaneous value Ih and as the delayed value Iv. The delay can be implemented by 4 88232 e.g. an RC delay circuit or a sampling principle 15. The polarity of the output a of the comparator 14 depends on which of the current signals Ih, Iv is greater. This signal a controls the gate circuit 12 so that the polarity of the output b of the gate circuit 12 is reversed if the current derivative 5 is negative at the end of the delay period.

If the instantaneous value Ih is greater than the delayed value Iv, i.e. the output-input current Iout increases, the polarity of the output of the comparator 14 and the gate circuit 12 remains unchanged and the conversion ratio of the converter 11 is adjusted in the same direction as before. Only when the instantaneous current Ih becomes smaller than the delayed current Iv (the output current Iout decreases) does the polarity of the output a of the comparator 14 change and the conversion ratio of the converter 11 begins to be adjusted in the opposite direction. The process repeats, causing the output current Iout to oscillate around the maximum value 15 as shown in Figure 2.

Figure 3 shows the topology of the main circuit of the control method according to the invention and the current measurement. The switch is marked with the letter S, the diode with the letter D, the capacitance with the letter C and the inductance with the letter L.

The current measuring circuit shown in Fig. 4 consists of the main circuit switch S1 (diode D and inductance L as in a step-down switch), however, so that the polarities of the components and voltages are opposite to the conventional connection.

With the current measuring circuit according to Fig. 4, e.g. the following benefits. First, current measurement and switch S! the control is at the same potential, thus simplifying the control circuit, which in turn lowers the price of the 30 measuring circuits substantially. Second, the internal resistance of the switch SL can be used to measure the current, as a result of which a separate measuring resistor is not required. As a result, losses are reduced and efficiency is increased. Third, the switch can be implemented with an N-type fetil or an NPN transistor, which are cheaper than a P-Fet or a 35 PNP transistor with the same current and voltage resistance values.

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The basic idea of the current measuring circuit shown in Fig. 4 is as follows.

The average output current iL can be calculated by measuring the current flowing through the switch S, if the switch S, the conduction time t ,, the conduction time tD of the zero diode D 5 and the time T of the whole period are known.

The method is based on the fact that the current of the inductance L increases linearly under the conduction of the switch S, and decreases linearly under the conduction of the diode D, whereby the average load current is obtained from the equation (time zero-10 is the switching moment) i T i C 'i, + td TL - iL (t ) dt - iL (t) dt + - iL (t) dt (1)

15 tJ tJ tJ

0 0 t.

Since the current curve shape increases or decreases linearly between the maximum-20 current value 1, ^ and the minimum value of the current, Equation (1) - * - · t-d: is obtained. iL - (Wita) / 2 + - (1, ^ + 1, ^) / 2: 25 τ τ t. + td --- (1, + 1, ^) / 2 (2)

30 T

This can also be written in the form 35c.

· __ t. + Td 1 Λ iL --— 1 iL (t) dt (3): '· 40 τ t. J. ··, where 45 6 88232 t * + 5 k2 - - (4)

T

10 t, and Xi - - J iL (t) dt (5) 0 15

The technical implementation of the current measuring circuit shown in Fig. 4 is as follows.

The signal Ui is proportional to the switch S! to the current flowing through it and 20 with the switch S: also leading to the load current iL.

From the output u3 of the connection formed by the analog switch S2 and the integrating RC circuit R1C1, a signal 25 t proportional to the integral part x1 of Equation (3) is obtained, 1 Γ u3 ~ - I u ^ t 30 * 0

The op amp learn acts as a voltage follower (u * u3) and prevents the RC circuit R1C1 from being loaded.

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The analog switch S3 and the RC circuit R2G2 perform the multiplication in equation (3) with (t, + td) / T.

t. + td 40 1 Γ t, + td u6 »- I u * dt * - u4

T J T

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The op2 operational amplifier acts as a voltage follower. The comparator compl serves as a current indicator of the zero diode D based on the examination of the polarity of the voltage across the diode D (no current 5 flows through the diode D if the voltage u ^ O). The signal u, - "1" from the comparator compl, when the diode D conducts, i.e. t, <t ^ t, + td. The control signal u of the power switch S indicates the current flowing directly through the switch (if and when u ^ CUjJ.

The load current iL is non-zero if the current of either diode D or switch S, 10 is non-zero. This is accomplished by a or-member stallion with an output voltage u10 to "1" for a time of 0 <t <t, + td and zero only when the current is open in the interval t, + td <t <T (with a continuous current t (+ td - T).

Figure 5 shows currents and voltages with an open current and Figure 6 shows currents and voltages with a continuous current, respectively. The following assumptions are made in Figures 5 and 6 and the signals are labeled as follows.

Assumptions: ....: 20: - uB and assumed to be flat (¾> υΜ) - losses are not taken into account except for the diode threshold voltage ud - the time constants of the RC circuit are large.

*. . . ‘I

25 Signals: - u ,: switch S, measured current instantaneous value - Uj: RC circuit R, C, input voltage - u ,: RC circuit R, C, output voltage 30 - u4: RC circuit R, C, output voltage buff separated (-u,) - u5: input voltage of RC circuit RjC2 - Uj: output voltage of RC circuit RiCJ · '- u ,: output voltage of RC circuit RjCj buffered (-u,) - Ug: power switch S, control voltage and at the same time signal (ip > 0) —35 - u ,: current detection of zero diode D (i ^ O) - u10: current detection of inductance L (iL> 0) 8 88232

Fig. 7 schematically shows an embodiment of the control method according to the invention, in which the solar panel 16 charges the battery 17 via a converter 11. Instead of the solar panel 16, 5 wind generators, a fuel cell, a thermoelectric generator, etc. can of course be used.

Only some preferred embodiments of the invention have been described above and it will be apparent to those skilled in the art that numerous modifications may be made thereto within the scope of the inventive idea set forth in the appended claims.

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Claims (8)

9 88232 A method for controlling the output current (Iout) of a DC / DC converter (11), wherein the energy generating device (16) is adapted to supply 5 energy to the storage device (17) via the converter (11), characterized in that the control method measures 11) an internal current (I,) by means of the measuring circuit (13) that the signal (I) obtained from the measuring circuit (13) is fed directly to the reference element (14) as an instantaneous value (Ih) and a delayed value (Iv), whereby the reference element (14) ) the polarity of the output (a) depends on which of the current signals (Ih, lv) is larger, and that the output signal (a) of the comparator (14) controls the gate circuit (12) so that the polarity of the output (b) of the gate circuit (12) changes , if the current derivative is negative at the end of the delay period. 15 Method according to claim 1, characterized in that the current (Ih) applied to the reference element (14) as an instantaneous value is greater than the delayed value (Iv) of the current, i.e. as the output current (Iout) of the converter (11) increases, the reference element (14) and the gate circuit The polarity of the output 20 (12) remains unchanged and the conversion ratio of the converter (11) is adjusted in the same direction as before. ... "A method according to claim 1, characterized in that when the instantaneous value (Ih) of the current becomes smaller than the delayed value (Iv) of the current 25, i.e. as the output current (Iout) of the converter (11) decreases, the output (a) of the reference element (14) ) the polarity changes and the conversion ratio of the converter (11) starts to be adjusted in the opposite direction. Method according to one of Claims 1 to 3, characterized in that the output current (Iout) of the converter (11) oscillates around a maximum value. Use of a control method according to one of Claims 1 to 4, characterized in that the solar panel (16) is adapted to charge the battery (17) via a converter (11). 10 88232 Use of a control method according to one of Claims 1 to 4, characterized in that the wind generator (16) is adapted to charge the battery (17) via a converter (11). 5 Use of a control method according to one of Claims 1 to 4, characterized in that the fuel cell (16) is adapted to charge the battery (17) via a converter (11). Use of a control method according to one of Claims 1 to 4, characterized in that the thermoelectric generator (16) is adapted to charge the battery (17) via a converter (11). 11 38232