KR20070011791A - Switching mode power supply - Google Patents

Abstract

A switching mode power supply having a constant current output characteristic is provided to restrict an output current by increasing or decreasing a switching frequency according to a voltage of a power unit in proportion to an output-side voltage. A transformer(110) has a main winding and an auxiliary winding(112) wound around an input side, and an output winding(113) wound around an output side. A switching element(120) is connected to the main winding of the transformer and is switched on/off at a certain frequency to transform voltage and current at the output winding. A power unit(130) is connected to the auxiliary winding to output a desired power. A control unit receives the power from the power unit to reduce or increase a switching frequency of the switching element.

Description

Switching Mode Power Supply with Constant Current Output

1 is a circuit diagram schematically showing an example of a conventional switched mode power supply.

2 is a waveform diagram illustrating an operation waveform in a conventional switching mode power supply.

Figure 3a is a graph showing the constant current-constant voltage output characteristics during charging of a conventional battery, Figure 3b is a graph again drawn with the current of the Y-axis in Figure 3a as power, Figure 3c is the frequency of the Y-axis power in Figure 3b 3D is a graph illustrating the constant power-constant voltage output characteristics.

4 is a circuit diagram schematically showing a configuration of a switching mode power supply having a constant current output characteristic according to the present invention.

5A and 5B are circuit diagrams showing an example of a switching mode power supply having a constant current output characteristic according to the present invention.

FIG. 6 is a circuit diagram schematically illustrating a sawtooth wave oscillator of the circuit of FIG. 5A or 5B.

FIG. 7 is a graph illustrating a state in which the discharge time varies depending on the operation of the discharge constant current source in the sawtooth oscillator of FIG. 5A or 5B.

8 is a graph showing the relationship between the switching frequency and the voltage in a switching mode power supply having a constant current output characteristic according to the present invention.

9A and 9B are graphs illustrating output characteristics by a switching mode power supply having a constant current output characteristic according to the present invention.

<Description of Symbols for Main Parts of Drawings>

100; Switching mode power supply according to the present invention

110; Transformer 120; Switching element

130; A power supply 1400; Control

150; Switching element 160; Current sensor

The present invention relates to a switched mode power supply, and more particularly, to a switched mode power supply having a constant current output characteristic.

Referring to FIG. 1, an example of a conventional switched mode power supply is shown as a schematic circuit diagram.

As shown, the conventional switching mode power supply includes a rectifier 1 for rectifying AC power into DC, a transformer 2 for inducing a voltage from an input side to an output side by a power supply and a switching operation from the rectifier 1, A switching element 3 connected to an input side of the transformer 2 and repeating an on / off operation at a predetermined cycle to induce a voltage to an output side, and a control unit controlling an on / off pulse width of the switching element 3; It consists of 4). The switch mode power supply in this configuration is also referred to as a fly-back converter. Here, the rectifier 1 may be a conventional battery.

The operation mode of the switched mode power supply includes a continuous conduction mode (CCM) and a discontinuous conduction mode (DCM). It is easy to cope with the case where the range of input voltage is wide, and since the diode on the output side does not need to be a high performance, the discontinuous conduction mode is usually used a lot.

Referring to FIG. 2, an operational waveform is shown in a conventional switched mode power supply.

As shown, in the discontinuous conduction mode, energy is accumulated on the input side (magnetization inductance) of the transformer while the switching element is on, and all of the energy is passed to the output side or is lost while the switching element is off and the input side (magnetization inductance) is lost. ) Energy becomes zero. In this case, the power P ₀ passed to the output side is expressed by Equation 1 below.

Where P ₀ is the output power, L _m is the transformer input side magnetization inductance, I _pk is the peak current, f is the switching frequency, and η is the efficiency.

Therefore, it can be seen that the output power P ₀ is proportional to the frequency f in the conventional switching mode power supply.

On the other hand, for the charger it is necessary to limit the maximum output current. When the battery (secondary battery) discharges a lot and the voltage is low, the battery is charged with a limited maximum current, and then charged while maintaining the voltage when the target voltage is reached. After that, the charging current gradually decreases to almost zero and becomes full charge. This output characteristic is called CC-CV (Constant Current-Constant Voltage).

This CC-CV output characteristic is shown in FIG. 3A. When the voltage is too low, the switching mode power supply is difficult to operate normally, and the battery may be shut down because it may be in an overdischarge state. In FIG. 3A, when the current on the Y-axis is used as the power, the power is again shown in FIG. 3B. Here, as shown in Equation 1, since the output power P ₀ is proportional to the frequency f, it is shown in FIG. Comparing FIG. 3B with FIG. 3C, it can be seen that only the labels on the Y-axis are changed.

Therefore, by using this characteristic, the frequency is changed in proportion to the output voltage of the switching mode power supply, and if the maximum value of the output current I _pk is constantly limited, the maximum output current can be controlled constantly. For reference, if the switching frequency is constant and only the maximum value of the output current is limited, constant power-constant voltage (CP-CV) output characteristics are obtained as shown in FIG. 3d. This is dangerous because a very large current can flow when the battery voltage is low.

In addition, as shown in FIG. 3C, when the switching frequency f is changed in proportion to the output voltage and the maximum value of the output current is limited, the CC-CV output characteristic can be obtained.

However, in a typical low-cost charger or adapter, the input side and output side of the switched mode power supply are insulated for safety. Therefore, it is not easy to transfer the voltage on the output side to the input side with the control section. Therefore, the switching frequency f cannot be changed in proportion to the output voltage on the output side, which leads to a problem in that it is difficult to obtain CC-CV characteristics in the conventional low-cost switching mode power supply. Of course, it is conceivable to further provide a circuit for feeding back the output voltage on the output side, and to allow the control unit to determine the switching frequency. However, in this case, there is a problem in that the price of the switching mode power supply becomes expensive because a circuit for sensing the output voltage on the output side and feeding back to the controller is further formed.

SUMMARY OF THE INVENTION The present invention has been made to overcome the above-mentioned problems, and an object of the present invention is to provide a switching mode power supply having a constant current output characteristic by adding a simple circuit to the input side without adopting a circuit for sensing and feeding back an output voltage on the output side. It is.

In order to achieve the above object, a switching mode power supply having a constant current output characteristic according to the present invention includes a transformer in which a main winding and an auxiliary winding are wound on an input side, and an output winding wound on an output side, and connected to an input main winding of the transformer. At the same time, a switching element that is turned on / off at a predetermined frequency to transform a predetermined voltage and current into an output winding on the output side, a power supply connected to an auxiliary winding of the transformer to output a predetermined power, and receives power from the power supply. And a control unit which increases or decreases the switching frequency of the switching element in proportion to the power source.

Here, the power supply unit includes a diode whose anode is connected to one end of the auxiliary winding to rectify the voltage, and a capacitor connected to the cathode of the diode to smooth the voltage and applied to the controller.

In addition, the voltage applied to the control unit by the power supply unit is proportional to the output voltage by the output side output winding within a predetermined error range.

The control unit may further include a first control unit configured to output an enable signal when the voltage of the power supply unit is greater than a reference voltage by comparing the voltage of the power supply unit with a reference voltage and a predetermined period according to the enable signal of the first control unit. A sawtooth oscillator for adjusting the discharge time of the sawtooth wave is provided, and by the output waveform of the sawtooth oscillator may comprise a second control unit having a square wave oscillator for adjusting the on / off period of the switching element to a square wave.

In addition, the first control unit and at least one comparator for comparing the voltage of the power supply unit with at least one reference voltage, and outputs a state inversion signal when the voltage of the power supply unit is greater than the reference voltage, the state of each comparator At least one RS flip-flop may be set as an inverted signal and output an enable signal to the sawtooth oscillator of the second controller.

In addition, a plurality of the reference voltages are provided, and each reference voltage may be set differently.

Each RS flip-flop may be reset by a waveform of a square wave oscillator.

In addition, the sawtooth oscillator of the second control unit is connected to the charging constant current source and the charging constant current source in series charge and discharge, the capacitor generating the sawtooth and at least one or more connected to the capacitor in parallel to adjust the discharge time It may include at least one discharge constant current source.

In addition, each of the discharge constant current source may be set different from the discharge constant current.

In addition, each discharge constant current source is enabled or disabled by the RS flip-flop selected from the first control unit, so that the discharge time of the sawtooth oscillator may vary.

In addition, the switching element may be further connected to a current sensor for sensing the current flowing through the switching element to output a voltage.

The second control unit may include: a main comparator receiving the voltage input from the current sensor and a preset correction voltage; a main RS flip-flop reset by the output signal of the main comparator, and set by the square wave oscillator; And an end gate for turning on / off the switching element by an output signal of the square wave oscillator and the main RS flip-flop.

The second control unit may include a main comparator receiving a voltage input from the current sensor and a preset correction voltage, a main RS flip flop reset by an output signal of the main comparator, and set by the square wave oscillator; And a NOR gate for turning on / off the switching element by an output signal of the square wave oscillator and the main RS flip-flop.

As described above, the switching mode power supply having the constant current output characteristic according to the present invention has a power supply unit at the input side in proportion to the output side voltage, and increases or decreases the switching frequency according to the voltage of the power supply unit, thereby limiting the output current to improve the constant current characteristic. You can get it. Of course, since there is a predetermined error range between the input side auxiliary winding and the output side output winding, CC-CV characteristics can be obtained although there is a slight error in current or voltage. In addition, the present invention can obtain more accurate CC-CV characteristics if the cross regulation performance is improved between the auxiliary winding on the input side and the output winding on the output side. Here, the cross regulation refers to a case where the voltage of the power supply unit by the input side auxiliary winding is also controlled constantly by controlling the output voltage on the output side. However, due to leakage inductances in the windings of the input and output sides, the cross regulation performance is slightly degraded.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings such that those skilled in the art may easily implement the present invention.

4, there is shown a switching mode power supply having a constant current output characteristic in accordance with the present invention.

As shown, in the switching mode power supply 100 having the constant current output characteristic according to the present invention, a main winding 111 and an auxiliary winding 112 are wound on an input side, and an output winding 113 is wound on an output side. 110 and a switching element 120 connected to the input main winding 111 of the transformer 110 and simultaneously being turned on / off at a predetermined frequency or period to transform a predetermined voltage and current to the output winding 113 on the output side; And a power supply unit 130 connected to the input side auxiliary winding 112 of the transformer 110 to output a predetermined power in proportion to the output side output winding 113, and receiving power from the power supply unit 130 to the power supply. And a control unit 1400 that proportionally increases or decreases the switching frequency of the switching element 120, and a current sensor 150 that detects a current of the switching element 120, converts it into a voltage, and outputs the voltage to the control unit. The.

Here, the switching element 120 may be any one selected from a general P-channel field effect transistor, an N-channel field effect transistor, or an equivalent thereof, but the type is not limited thereto.

In addition, it is assumed that the voltage applied to the control unit 1400 by the power supply unit 130 is proportional to the output voltage by the output winding 113 on the output side within a predetermined error range as described above. Of course, for this purpose it is natural that the auxiliary winding 112 wound on the input side and the output winding 113 wound on the output side should be wound on the same iron piece.

In addition, the power supply unit 130 has an anode connected to one end of the auxiliary winding 112 to rectify the voltage, and is connected to the cathode of the diode 131 to smooth the voltage to the controller 1400. The capacitor 132 is applied. However, in the present invention, the configuration of the power supply unit 130 is not limited to such a circuit, and the circuit shown in the drawing is only an example.

5A and 5B are circuit diagrams showing an example of a switching mode power supply having a constant current output characteristic according to the present invention.

As shown in FIG. 5A, the control unit 1400 of the switching mode power supply according to the present invention greatly compares the voltage of the power supply unit 130 with a reference voltage, and enables the voltage when the voltage of the power supply unit 130 is greater than the reference voltage. A first controller 1410 for outputting a signal and a sawtooth oscillator 1421 for adjusting a discharge time of a sawtooth wave having a predetermined period according to the enable signal of the first controller 1410 are provided. And a second control unit 1420 having a square wave oscillation unit 1422 for outputting the on / off frequency or period of the switching element 120 by adjusting the square wave by the output waveform.

In the following description, it should be noted that the circuit configuration of the first control unit 1410 or the second control unit 1420 of the configuration of the control unit 1400 is just one example and does not limit the present invention to such a circuit. do.

In the following description, the first controller 1410 includes at least one comparator that outputs a state reversal signal when the voltage from the power supply unit 130 is greater than the reference voltage by comparing the voltage from the at least one reference voltage. And at least one RS flip-flop, which is set as a state inversion signal of the comparator and outputs an enable signal to the sawtooth oscillator 1421 of the second controller 1420. That is, the comparator may include a first comparator 1411, a second comparator 1412, a third comparator 1413, and a fourth comparator 1414, but the present invention is not limited to the number of comparators. In addition, the first comparator 1411 has a first reference voltage Ip1, the second comparator 1412 has a second reference voltage Ip2, and the third comparator 1413 has a third reference voltage Ip3. The fourth reference voltage Ip4 is input to the fourth comparator 1414. The reference voltage may be set to the first reference voltage Ip1 <the second reference voltage Ip2 <the third reference voltage Ip3 <the fourth reference voltage Ip4, or vice versa. Accordingly, the RS flip-flop may also include a first RS flip-flop 1415, a second RS flip-flop 1416, a third RS flip-flop 1417, and a fourth RS flip-flop 1418.

In this manner, when the voltage by the power supply unit 130 is greater than the first reference voltage Ip1, the first RS flip-flop 1415 is set by the first comparator 1411 to set a predetermined signal (for example, a high signal or an in). And a second RS flip-flop 1416 is set by the second comparator 1412 when the voltage obtained from the power supply unit 130 is greater than the second reference voltage Ip2. The third comparator 1413 outputs a predetermined signal (for example, a high signal or an enable signal) to the second control unit 1420, and the voltage obtained from the power supply unit 130 is greater than the third reference voltage Ip3. The third RS flip-flop 1417 is set to output a predetermined signal (for example, a high signal or an enable signal) to the second controller 1420, and the voltage obtained from the power supply 130 is the fourth reference voltage Ip4. If larger, the fourth RS flip-flop 1418 is set by the fourth comparator 1414, and a predetermined signal (e.g., For example, a high signal or an enable signal) is output to the second control unit 1420. More specifically, the enable signal of the first RS flip-flop 1415, the second RS flip-flop 1416, the third RS flip-flop 1417, and the fourth RS flip-flop 1418 may be a sawtooth oscillator of the second controller 1420. It is outputted to 1421.

The first RS flip-flop 1415, the second RS flip-flop 1416, the third RS flip-flop 1417, and the fourth RS flip-flop 1418 are reset by the square wave oscillator 1422 of the second controller 1420. It is to be possible. That is, when a predetermined signal (for example, a low signal) is input to the reset terminal by the square wave oscillator 1422, each RS flip-flop outputs a predetermined signal (for example, a low signal or a disable signal) to the second controller 1420. Output to the sawtooth oscillator 1421 to return the discharge time of the sawtooth wave to a preset value.

Subsequently, the second control unit 1420 includes a sawtooth oscillator 1421 which receives a predetermined signal from each RS flip-flop, a square wave oscillator 1142 for outputting a square wave by the sawtooth oscillator 1421, and the switching element. Reset by the main comparator 1423 and the main comparator 1423 which receive the voltage of the switching element 120 and the preset correction voltage Vc from the current sensor 150 for sensing the current of 120, And a main RS flip-flop 1424 set by the square wave oscillator 1422, an end gate 1425 receiving a predetermined signal from the square wave oscillator 1422 and the main RS flip-flop 1424. Of course, the switching element 120 is turned on / off at a predetermined frequency by the end gate 1425.

In this way, the second controller 1420 has a different frequency (eg, a longer discharge time) from the sawtooth oscillator 1421 according to an enable signal input from each RS flip-flop of the first controller 1410. Or it outputs a sawtooth wave of a period. Therefore, the frequency or period of the square wave oscillator 1422 connected thereto is also changed (lowered), so that the on / off frequency of the switching element 120 is also lowered.

In addition, the main comparator 1423 of the second controller 1420 may reset the main RS flip-flop 1424 when the voltage (current) detected from the current sensor 150 is greater than a preset correction voltage Vc. do. Then, the main RS flip-flop outputs a predetermined signal (for example, a low signal) to the end gate 1425 so that the switching element 120 is turned off. In addition, the main RS flip-flop 1424 is set by a predetermined signal (for example, a high signal) input from the square wave oscillator 1422 so that the switching element 120 is turned on again by the end gate 1425. do.

단자를 갖는 주RS 플립플롭(1424')으로 대체될 수 있고, 또한 이에 따라 엔드 게이트(1425)은 노어 게이트(1425')로 대체될 수 있다. 물론, 이러한 구성을 한다고 해도 동작은 위에서 설명한 바와 같으므로 이것의 동작 설명은 생략하기로 한다.Here, as shown in Fig. 5B, the main RS flip-flop 1424 having a Q terminal is

It can be replaced with a main RS flip-flop 1424 'with terminals, and thus the end gate 1425 can be replaced with a NOR gate 1425'. Of course, even with such a configuration, since the operation is as described above, the description of the operation thereof will be omitted.

Referring to FIG. 6, a sawtooth oscillator in the circuit of FIG. 5A or 5B is schematically illustrated. Here, it should be understood that the circuit configuration of the sawtooth oscillator is only one example and does not limit the present invention to such a circuit configuration.

As illustrated, the sawtooth oscillator 1421 of the first control unit 1410 of the above-described components is connected to one charging constant current source 1421a and the charging constant current source 1421a in series to charge and discharge a predetermined period. And a capacitor 1421b for generating a sawtooth wave of at least one, and at least one or more discharge constant current sources connected in parallel with the capacitor 1421b to control a discharge time. The discharge constant current source may include, for example, a first discharge constant current source 1421c, a second discharge constant current source 1421d, a third discharge constant current source 1421e, and a fourth discharge constant current source 1421f. The present invention is not limited to these numbers. That is, the number of the discharge constant current sources is formed to correspond to the number of comparators provided in the first control unit 1410. Meanwhile, each of the discharge constant current sources may be set to discharge at different values. For example, the first discharge constant current source 1421c consumes a current of Id1, the second discharge constant current source 1421d consumes a current of Id2, and the third discharge constant current source 1421e receives a current of Id3. And the fourth discharge constant current source 1421f consumes a current of Id4.

FIG. 7 is a graph illustrating a state in which the discharge time varies depending on the operation of the discharge constant current source in the sawtooth oscillator of FIG. 5A or 5B.

As illustrated, the present invention provides a first discharge constant current when an enable signal is input from the first RS flip-flop 1415, the second RS flip-flop 1416, the third RS flip-flop 1417, and the fourth RS flip-flop 1418. The circle 1421c, the second discharge constant current source 1421d, the third discharge constant current source 1421e, and the fourth discharge constant current source 1421f are all operated. Therefore, in this state, the discharge time of the capacitor 1421b is shortest, and therefore the discharge time of the sawtooth wave is also shortest. Of course, the on / off frequency of the switching element 120 is the highest.

Subsequently, when an enable signal is input from the first RS flip-flop 1415, the second RS flip-flop 1416, and the third RS flip-flop 1417, a first discharge constant current source 1421c and a second discharge constant current source 1421d are provided. The third discharge constant current source 1421e is operated. Therefore, in this state, the discharge time of the capacitor 1421b is long for the second time, and therefore the discharge time of the sawtooth wave also becomes second for the second time. Of course, at this time, the frequency of the switching element 120 is slightly reduced.

Subsequently, when an enable signal is input from the first RS flip-flop 1415 and the second RS flip-flop 1416, the first discharge constant current source 1421c and the second discharge constant current source 1421d are operated. Therefore, in this state, the discharge time of the capacitor 1421b is extended for the third time, and therefore the discharge time of the sawtooth wave is also extended for the third time. Of course, at this time the frequency of the switching element 120 becomes smaller.

Finally, when the enable signal is input from the first RS flip-flop 1415, only the first discharge constant current source 1421c is operated. Therefore, in this state, the discharge time of the capacitor 1421b becomes fourth. Therefore, the discharging time of the sawtooth wave is also extended fourth. Of course, at this time, the on / off frequency of the switching element 120 becomes smaller.

Thus, in the present invention, when the voltage of the power supply unit 130 by the auxiliary winding 112 on the input side becomes proportional to the output voltage by the output winding 113 on the output side, the capacitor of the sawtooth wave oscillating unit 1421 is gradually increased. The time for discharging 1421b becomes long, and thus the on / off frequency and the current Ipk of the switching element 120 become small. In other words, even if an output voltage sensing circuit or the like is not provided on the output side to detect the output voltage on the output side, if the output voltage on the output side becomes small in a simple manner, the output voltage and output current can be lowered by lowering the on / off frequency of the switching element. It becomes possible.

With the above configuration, the switching mode power supply having the constant current output characteristic according to the present invention operates as follows. Here, since the operation of the transformer and the switching device has been described together with the above configuration, description thereof will be omitted, and an operation relationship between the power supply unit 130 and the control unit 1400 will be mainly described.

First, as described above, since the power supply unit 130 generates power by the auxiliary winding 112 on the input side, the power supply unit 130 outputs a predetermined power to the control unit 1400 in proportion to the output voltage of the output winding 113 on the output side. Then, the control unit 1400 controls the switching element 120 at a switching frequency f proportional to the voltage V of the power supply unit 130 as shown in FIG. 8. This is explained in more detail.

First, the operation of the first control unit 1410 will be described.

The voltage of the power supply unit 130 by the auxiliary winding 112 wound on the input side of the transformer 110 is input to the non-inverting terminal of each comparator. That is, the non-inverting terminal of the first comparator 1411 in which the first reference voltage Ip1 is input to the inverting terminal, and the non-inverting terminal of the second comparator 1412 in which the second reference voltage Ip2 is input to the inverting terminal. , To the non-inverting terminal of the third comparator 1413 in which the third reference voltage Ip3 is input to the inverting terminal, and to the non-inverting terminal of the fourth comparator 1414 in which the fourth reference voltage Ip4 is input to the inverting terminal, respectively. The voltage of the power supply unit 130 is input. Here, it is assumed that the voltage of the power supply unit 130 is proportional to the output voltage by the output winding 113 wound on the output side of the transformer 110 as described above.

In this case, when the voltage of the power supply unit 130 is greater than or equal to the first reference voltage Ip1, the first comparator 1411 inputs a predetermined signal (for example, a high signal) to the S terminal of the first RS flip-flop 1415. Thus, the first RS flip-flop 1415 is set. In this manner, the first RS flip-flop 1415 outputs a predetermined signal (for example, a high signal or an enable signal) to the sawtooth oscillator 1421 of the second controller 1420 through the Q terminal.

In addition, when the voltage from the power supply unit 130 is greater than or equal to the second reference voltage Ip2, the second comparator 1412 sends a predetermined signal (for example, a high signal) to the S terminal of the second RS flip-flop 1416. By input, the 2RS flip-flop 1416 is set. In this way, the second RS flip-flop 1416 outputs a predetermined signal (for example, a high signal or an enable signal) to the sawtooth oscillator 1421 of the second controller 1420 through the Q terminal.

In addition, when the voltage from the power supply unit 130 is greater than or equal to the third reference voltage Ip3, the third comparator 1413 sends a predetermined signal (for example, a high signal) to the S terminal of the third RS flip-flop 1417. By input, the 3RS flip-flop 1417 is set. In this manner, the 3RS flip-flop 1417 outputs a predetermined signal (for example, a high signal or an enable signal) to the sawtooth oscillator 1421 of the second controller 1420 through the Q terminal.

In addition, when the voltage from the power supply unit 130 is greater than or equal to the fourth reference voltage Ip4, the fourth comparator 1414 sends a predetermined signal (for example, a high signal) to the S terminal of the fourth RS flip-flop 1418. By input, the 4RS flip-flop 1418 is set. In this manner, the fourth RS flip-flop 1418 outputs a predetermined signal (for example, a high signal or an enable signal) to the sawtooth oscillator 1421 of the second controller 1420 through the Q terminal.

Next, the operation of the second control unit 1420 will be described.

The sawtooth oscillator 1421 of the second control unit 1420 has an enable signal from the first RS flip-flop 1415, the second RS flip-flop 1416, the third RS flip-flop 1417, and the fourth RS flip-flop 1418. (Or a high signal) is input, the first discharge constant current source 1421c, the second discharge constant current source 1421d, the third discharge constant current source 1421e, and the third discharge constant current source 1421e when the capacitor 1421b is discharged. All of these are operated so that the discharge time is relatively shortest. Therefore, at this time, the frequency or period of the square wave oscillation unit 1422 is also the shortest, and thus the on / off frequency of the switching element 120 is the largest.

Subsequently, the sawtooth oscillator 1421 of the second controller 1420 receives a capacitor 1421b when an enable signal is input from the first RS flip-flop 1415, the second RS flip-flop 1416, and the third RS flip-flop 1417. ), The first discharge constant current source 1421c, the second discharge constant current source 1421d, and the third discharge constant current source 1421e are operated so that the discharge time is second long. Therefore, at this time, the frequency or period of the square wave oscillator 1422 is also secondly long, and thus the on / off frequency of the switching element 120 is relatively small.

Subsequently, when the enable signal is input from the first RS flip-flop 1415 and the second RS flip-flop 1416, the sawtooth oscillator 1421 of the second control unit 1420 discharges the first discharge constant current when the capacitor 1421b is discharged. The circle 1421c and the second discharge constant current source 1421d are operated so that the discharge time is extended for the third time. Therefore, at this time, the frequency or period of the square wave oscillation unit 1422 is also extended for the third time, and thus the operating frequency of the switching element 120 is further reduced.

Subsequently, when the enable signal is input from the first RS flip-flop 1415, the sawtooth oscillator 1421 of the second control unit 1420 operates the first discharge constant current source 1421c to discharge the capacitor 1421b. Make the discharge time of the fourth longest. Therefore, at this time, the period of the square wave oscillation unit 1422 is also extended for the fourth time, so that the operating frequency of the switching element 120 is the smallest.

That is, as more RS flip-flops output the enable signal, more discharge constant current sources operate, so that the discharge time of the capacitor is shorter and the switching frequency is higher. In addition, the smaller the voltage from the power supply unit, the smaller the number of comparators for setting the RS flip flop, so that a smaller discharge constant current source is operated, resulting in a longer discharge time of the capacitor, resulting in a lower switching frequency. In sum, the second control unit 1420 outputs the largest switching frequency when the voltage of the power supply unit 120 is relatively large, and outputs the smallest switching frequency when the voltage of the power supply unit 120 is relatively small. By doing so, the voltage versus frequency characteristics shown in FIG. 8 are satisfied.

On the other hand, when the current sensed from the current sensor 150, that is, the voltage is greater than the preset correction voltage Vc, the second controller 1420 outputs a state reversal signal to output the main RS flip-flop 1424. ) Will be reset. Then, the main RS flip-flop 1424 outputs a predetermined signal (for example, a low signal), so that the switching element 120 is provided by the end gate 125 even when the high signal is output from the square wave oscillator 1422. ) Off. In other words, the width of the frequency output from the square wave oscillator 1422 is reduced so that the current flowing through the switching element 120 does not flow above the peak current.

On the other hand, when the high signal is input from the square wave oscillator 1422 again to the S terminal of the main RS flip-flop 1424, the main RS flip-flop 1424 is set again to provide a predetermined signal (for example, a high signal). It outputs to the end gate 1425. Then, the end gate 1425 turns on the switching element 120 for a predetermined period of time output from the square wave.

8 is a graph showing the relationship between the switching frequency and the voltage in a switching mode power supply having a constant current output characteristic according to the present invention.

As shown, the control unit 1400 changes the on / off frequency of the switching element 120 according to the voltage of the power supply unit 130. Since the control unit 1400 is controlled to output at a predetermined voltage, when the resistance of the load is not too small, the CV characteristic is obtained, and the operating voltage of the control unit 1400 also approaches V _OBJ of FIG. 8. However, when the resistance of the load is too small, the output voltage is reduced due to the limitation of the maximum output current Ipk, and the operating voltage of the controller 1400 is also reduced. At this time, as described above, the controller 1400 according to the present invention operates to obtain the CC characteristic by limiting the output current.

9A and 9B are graphs illustrating output characteristics by a switching mode power supply having a constant current output characteristic according to the present invention.

As shown in the figure, a slight error may occur in the current and voltage output characteristics because there is a slight error between the output winding on the output side and the power supply in terms of current or voltage. However, since the actual charger does not require perfect characteristics, the present invention is worthwhile. Of course, the present invention can obtain more sophisticated CC-CV characteristics if the cross regulation performance is improved.

As described above, the switching mode power supply having the constant current output characteristic according to the present invention increases and decreases the switching frequency according to the voltage of the power supply unit proportional to the output side voltage, thereby limiting the output current to obtain the constant current characteristic. Of course, since there is a predetermined error range between the input side auxiliary winding and the output side output winding, CC-CV characteristics can be obtained although there is a slight error in current or voltage. In addition, the present invention can obtain more accurate CC-CV characteristics if the cross regulation performance is improved between the auxiliary winding on the input side and the output winding on the output side.

What has been described above is only one embodiment for implementing a switching mode power supply having a constant current output characteristic according to the present invention, and the present invention is not limited to the above embodiment, and is claimed in the following claims. As described above, any person having ordinary knowledge in the field of the present invention without departing from the gist of the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

Claims (13)

A transformer in which a main winding and an auxiliary winding are wound on an input side, and an output winding is wound on an output side; A switching element connected to an input main winding of the transformer and simultaneously being turned on / off at a predetermined frequency to transform a predetermined voltage and current to an output winding on an output side; A power supply unit connected to an auxiliary winding of an input side of the transformer and outputting a predetermined power; And, And a control unit configured to receive power from the power supply unit and to increase or decrease the switching frequency of the switching element in proportion to the power supply. The method of claim 1, wherein the power supply unit An anode connected to one end of the auxiliary winding to rectify the voltage; And, Switching mode power supply having a constant current output characteristics characterized in that it comprises a capacitor connected to the cathode of the diode to smooth the voltage applied to the control unit. The switching mode power supply having a constant current output characteristic according to claim 1, wherein the voltage applied to the controller by the power supply unit is proportional to the output voltage by the output side output winding within a predetermined error range. The method of claim 1, wherein the control unit A first control unit comparing the voltage of the power supply unit with a reference voltage and outputting an enable signal when the voltage of the power supply unit is greater than the reference voltage; And, A sawtooth oscillator for adjusting the discharge time of the sawtooth wave having a predetermined period according to the enable signal of the first control unit is provided, and the square wave oscillator for adjusting the on / off period of the switching element to the square wave by the output waveform of the sawtooth oscillator Switching mode power supply having a constant current output characteristics, characterized in that it comprises a second control unit provided with. The apparatus of claim 4, wherein the first control unit compares a voltage of the power supply unit with at least one reference voltage, and outputs a state reversal signal when the voltage of the power supply unit is greater than the reference voltage. 12. A switching mode power supply having a constant current output characteristic comprising at least one RS flip-flop set as a state reversal signal of a comparator and outputting an enable signal to the sawtooth oscillator of the second control unit. 6. The switching mode power supply of claim 5, wherein the reference voltage is provided in plural, and each reference voltage is set differently. 6. The switched mode power supply of claim 5, wherein each RS flip-flop is reset by a waveform of a square wave oscillator. The apparatus of claim 7, wherein the sawtooth oscillator of the second control unit is connected to the charging constant current source and the charging constant current source in series and charged and discharged, thereby generating a sawtooth wave and at least one connected to the capacitor in parallel. A switching mode power supply having a constant current output characteristic, characterized in that it comprises at least one discharge constant current source for controlling the discharge time. 9. The switching mode power supply of claim 8, wherein each of the discharge constant current sources has a discharge constant current set differently. 10. The switching mode of claim 9, wherein each of the discharge constant current sources is enabled or disabled by an RS flip-flop selected from the first controller, so that the discharge time of the sawtooth oscillator is changed. Power supply. 5. The switching mode power supply of claim 4, wherein a current sensor for sensing and outputting a current flowing through the switching element as a voltage is further connected to the switching element. 12. The main RS of claim 11, wherein the second control unit is reset by an output signal of the main comparator and a main comparator that receives a voltage input from the current sensor and a preset correction voltage, and is set by the square wave oscillator. And a flip-flop, and an end gate for turning on / off the switching element by an output signal of the square wave oscillation unit and the main RS flip-flop. 12. The main RS of claim 11, wherein the second control unit is reset by an output signal of the main comparator and a main comparator that receives a voltage input from the current sensor and a preset correction voltage, and is set by the square wave oscillator. And a flip-flop, a NOR gate for turning on / off the switching element by an output signal of the square wave oscillator and the main RS flip-flop.

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