JP2004242391A - Power unit - Google Patents

Abstract

An object of the present invention is to improve a voltage drop of a sub power supply circuit and to save space when a main power supply circuit is lightly loaded in a multi-output switching power supply device.
A choke coil of a main power supply circuit and a choke coil of a sub power supply circuit used in a multi-output switching power supply device are wound around one core to form a composite choke coil L10. By providing a current flow path in the choke coil, the cutoff current value of the choke coil of the main power supply circuit is secured even if the load current of the main power supply circuit is reduced, and the voltage of the sub power supply circuit is reduced.
In addition, space can be saved by using a composite choke coil.
[Selection diagram] Fig. 1

Description

これをＶ１について解くと、
【数２】

Ｔ＝Ｔｏｎ＋Ｔｏｆｆ Ｖ１：出力電圧（Ｖ）
ＶＳ１：トランスＴ１二次側巻き線電圧（Ｖ） Ｔｏｎ：ＦＥＴ１ ｏｎ時間（Ｓ）
Ｔｏｆｆ：ＦＥＴ１ ｏｆｆ時間（Ｓ）
Ｖｉｎ：トランス一次側入力電圧（Ｖ） ｆ：スイッチング周波数（Ｈｚ）
ＮＳ１：トランス二次側巻き数 ＮＰ：トランス一次側巻き数
（１）の式から出力電圧Ｖ１は出力電流Ｉ１によらないことがわかる。従って、負荷電流が充分多い時は出力電流Ｉ１が変化してもスイッチングｏｎ時間も変化しないのでトランスＴ１の副電源用ＡＣ電圧ＶＳ２およびＶＳ３のパルス幅も変化しないのでＬ２、Ｌ３およびＣ２，Ｃ３により整流・平滑されたＤＣ電圧Ｖ４，Ｖ５も変化せず、ＩＣ２、ＩＣ３によりＶ２、Ｖ３は安定化される。
【０００６】
一方、負荷が軽くなるとチョークコイルＬ１を流れる電流がカットオフされる期間が生じるため図３（ｃ）に示すように不連続モードとなる。
ラインインピーダンス、二次側整流ダイオードによる電圧降下分を無視すると、スイッチングＦＥＴがｏｎしている時間にチョークコイルＬ１に流れる電流と、ｏｆｆしている時間に流れる電流が等しいという条件から、
【数３】

出力電流Ｉ１は不連続モードの電流波形を平均したものだから、
【数４】

これをＶ１について解くと、
【数５】

Ｌ１：二次側チョークコイルインダクタンス値（Ｈ） Ｉ１：出力電流（Ａ）
（２）式から出力電圧Ｖ１は出力電流Ｉ１に大きく依存することがわかる。従って、負荷電流が少ない時、Ｔｏｎを短くして出力電圧Ｖ１を一定にするように制御するのでトランスＴ１の副電源用ＡＣ電圧ＶＳ２およびＶＳ３のパルス幅も狭くなりＬ２、Ｌ３およびＣ２，Ｃ３により整流・平滑されたＤＣ電圧Ｖ４，Ｖ５が低下してＩＣ２、ＩＣ３で安定化することができなくなりＶ２、Ｖ３が低下してしまう。
【０００７】
なお、出力電圧Ｖ１が出力電流Ｉ１に依存しなくなるカットオフ電流臨界値Ｉｒは図３（ｂ）に示すように出力電流はチョークコイルＬ１に流れる電流を平均したものだから、
【数６】

となる。
【０００８】
以上に示す主電源回路の負荷が重いときと軽くなった場合の主電源回路の出力電流Ｉ１と副電源回路の出力電圧Ｖ４との関係を示したのが図４である。
主電源回路の負荷が軽くなり出力電流Ｉ１がチョークコイルＬ１のカットオフ電流臨界値より低下した時には、副電源回路の出力電圧Ｖ４は同図Ａに示すように急激に低下してしまう。
【０００９】
本発明は、このような従来の問題を解決するものでありチョークコイルＬ１，Ｌ２，Ｌ３を複合チョークコイルにすることにより省スペース化を図り、また、主電源回路において、ＩＣ１により直接制御されているＶ１の負荷Ｒ１があるチョークコイルのカットオフ電流値より軽い状態に変化しても、副電源回路の出力電圧が低下することを改善する多出力スイッチング電源装置を提供することを目的としている。
【００１０】
【課題を解決するための手段】
トランスの入力側に入力電源とスイッチ素子とが設けられ、トランスの出力側にはチョークコイル整流回路を備えた主出力電源回路と、同じくチョークコイル整流回路を備えた定電流の副出力電源回路とが設けられ、出力電源回路の主出力電圧のフィードバック信号によって該主出力電圧を安定化するスイッチ素子のパルス幅制御回路が設けられているフォワードコンバータタイプの多出力スイッチング電源装置において、
前記主出力電源回路のチョークコイルと副出力電源回路のチョークコイルは、ひとつのコアに巻き込んだ複合チョークコイルで構成され、主出力電源回路のチョークコイルから副出力電源回路のチョークコイルに電流の流れ道を設ける。さらに前記主出力電源回路から前記副出力電源回路に電流を供給する素子を設けても良い。また、前記複合チョークコイルを採用せず前記主出力電源回路から前記副出力電源回路に電流を供給する素子のみを設ける。以上の手段により主電源回路の負荷が軽くなっても副電源回路の電圧低下を防ぐ。
【００１１】
【発明の実施の形態】
以下に本発明における実施例を図面に基づき説明する。なお、本実施例の説明において、図２の回路構成部分と同一名称部分については同一符号を付し、その重複説明は省略する。
【００１２】
本発明の実施例を図１に示す。本実施例において特徴的なのはチョークコイルを一体化したことである。
【００１３】
一つのコアにトランスと同じ巻き線比で複数の線Ｌ１０−１、Ｌ１０−２、Ｌ１０−３を巻き込んだ複合チョークコイルＬ１０を採用することである。
基本的な動作は図２の従来の回路と同じである。異なる点は、複合チョークコイルをトランスとして作用させ、Ｌ１０−１を一次巻き線、Ｌ１０−２とＬ１０−３を二次巻き線として一次巻き線から二次巻き線に電流が流れるようにして、主電源回路の負荷が軽くなっても主電源回路のチョークコイルに流れる電流を確保して、軽負荷時の副電源回路の電圧低下を防ぐことである。
【００１４】
以下に動作を説明する。
従来のチョークコイルの場合、負荷Ｒ１にはＴ１のＮＳ１からＩ１が、負荷Ｒ２にはＴ１のＮＳ２からＩ２が、負荷Ｒ３にはＴ１のＮＳ３からＩ３が流れていた。
本発明の複合チョークコイルＬ１０の場合は、負荷Ｒ１にはＴ１のＮＳ１からＩ１が、負荷Ｒ２にはＴ１のＮＳ２からＩ６とＬ１０−１からＩ４が、負荷Ｒ３にはＴ１のＮＳ３からＩ７とＬ１０−１からＩ５が流れる。
ここで Ｉ２＝Ｉ４＋Ｉ６ Ｉ３＝Ｉ５＋Ｉ７である。
一方Ｔ１のＮＳ１からチョークコイルＬ１０−１に流れる電流はＩ１＋Ｉ４＋Ｉ５となる。チョークコイルＬ１０−１に流れる電流が前記（３）式に示す以下になるとＶ１が上昇するのでこの上昇を抑えるため、ＦＥＴ１のスイッチングｏｎ時間が少なくなるようにＩＣ１により制御される。ｏｎ時間が少なくなるとトランスＴ１の副電源用ＡＣ電圧ＶＳ２およびＶＳ３のパルス幅が狭くなるためＬ２、Ｌ３およびＣ２，Ｃ３により整流・平滑されたＤＣ電圧Ｖ４，Ｖ５が低下しレギュレータＩＣ２、ＩＣ３で安定化できない電圧まで低下すると負荷Ｒ２およびＲ３用電圧Ｖ２、Ｖ３が低下してしまうことになる。
負荷Ｒ２およびＲ３に流れる電流Ｉ４およびＩ５は一定電流であるので主電源の負荷Ｒ１が軽負荷になって電流Ｉ１が少なくなってもＩ４＋Ｉ５が前記（３）式に示すより多い電流であればＶ１が上昇することはなくＦＥＴ１のスイッチングｏｎ時間も変化することなくトランスＴ１の副電源用ＡＣ電圧ＶＳ２およびＶＳ３のパルス幅も変化せず、Ｌ２、Ｌ３およびＣ２，Ｃ３により整流・平滑されたＤＣ電圧Ｖ４，Ｖ５も変化せず、負荷Ｒ２およびＲ３用電圧Ｖ２、Ｖ３は安定化される。
【００１５】
以下に他の実施例を示す。
図１において主電源回路から副電源回路間に破線で示す抵抗Ｒ４，Ｒ５を付けて、主電源回路から副電源回路に電流を供給する方法である。この場合チョークコイルＬ１０−１に流れる電流は主電源のＩ１の他にＩ４＋Ｉ５＋Ｉ６＋Ｉ７となり前記実施例と同様副電源回路の電圧低下を改善できる。
また、Ｌ１０を複合トランス形でない通常のチョークコイルとして、主電源回路から副電源回路間に破線で示す抵抗Ｒ４，Ｒ５を付けて、主電源回路から副電源回路に電流を供給する方法でも副電源回路の電圧低下を改善できる。
【００１６】
以上の実施例では副電源回路は２回路で説明したが２回路にとらわれることはなく１個以上の複数個の副電源回路であれば良い。
【００１７】
【発明の効果】
以上述べたように、本発明によると、複合チョークコイルを使用することにより省スペース化が可能となり、また、チョークコイルをトランスとして作用させることにより主電源チョークコイルから副電源チョークコイルに電流を流すことにより主電源回路の負荷が軽くなっても副電源回路の電圧低下が発生することを改善することができる。
【図面の簡単な説明】
【図１】本発明における多出力スイッチング電源装置を説明する図である。
【図２】従来の多出力スイッチング電源装置を説明する図である。
【図３】チョークコイルＬ１の電流波形である。
【図４】主電源回路の出力電流と副電源回路の出力電圧との関係を示した図である。
【符号の説明】
Ｖｉｎ 入力電圧 ＩＣ１ パルス制御回路 ＦＥＴ１ スイッチ素子 Ｔ１ トランス ＮＰ トランス一次巻き数 ＮＳ１、ＮＳ２、ＮＳ３ トランス二次巻き
ＶＳ１、ＶＳ２、ＶＳ３ トランス二次電圧 ＣＤ１ａ、ＣＤ１ｂ、ＣＤ２ａ、ＣＤ２ｂ、ＣＤ３ａ、ＣＤ３ｂ 整流ダイオード Ｌ１、Ｌ２、Ｌ３ チョークコイル Ｌ１０ 複合チョークコイル Ｌ１０−１、Ｌ１０−２、Ｌ１０−３ 複合チョークコイル構成コイル Ｖ１、Ｖ２、Ｖ３ 負荷電圧 Ｖ４、Ｖ５ 副電源回路整流出力電圧 Ｃ１、Ｃ２、Ｃ３ コンデンサ ＩＣ１、ＩＣ２ シリーズレギュレータ Ｒ１，Ｒ２、Ｒ３ 負荷 Ｒ４，Ｒ５ 電流供給素子 Ｉ１，Ｉ２，Ｉ３ 負荷電流 Ｉ４，Ｉ５ 供給電流 Ｉ６、Ｉ７ 副電源回路電流 Ｉ８、Ｉ９ 供給電流[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a multi-output switching power supply used for electronic equipment.
[0002]
[Prior art]
FIG. 2 shows an example of a main configuration circuit of a conventional multi-output switching power supply device, in which a power supply for a load R1 is a main power supply circuit, and a power supply circuit for R2 and R3 is a sub-power supply circuit.
In FIG. 2, the DC input voltage Vin applied to the primary winding NP of the transformer T1 is converted into an AC voltage by periodically switching the FET1 by the control IC1. This AC voltage generates AC voltages VS1, VS2, VS3 in the secondary windings NS1, NS2, NS3 of the transformer T1 in proportion to the number of windings. The generated AC voltage becomes a DC voltage after rectification and smoothing by L1, L2, L3 and C1, C2, C3. Since the voltage V1 of the load R1 is the main power supply voltage, the switching of the FET1 is controlled by the IC1 so that the DC output voltage is kept constant with respect to the change of the input voltage and the load fluctuation. The voltage V2 of the load R2 and the voltage V3 of the load R3 are stabilized by using the regulators IC2 and IC3.
[0003]
[Patent Document 1]
JP-A-8-322250
[Problems to be solved by the invention]
By the way, in such a configuration, as many choke coils as the number of output voltages are required, and a space is required. Further, when the load R1 of the main power supply voltage V1 directly controlled by the IC1 changes to a lighter load state than a certain value, the voltage V1 rises. In order to suppress the rise, the switching on time of the FET1 controlled by the IC1 is controlled. Is controlled to decrease. When the ON time is reduced, the pulse width of the AC voltage VS2 and VS3 for the auxiliary power supply of the transformer T1 becomes narrower, so that the DC voltages V4 and V5 rectified and smoothed by L2, L3 and C2 and C3 decrease, and are stabilized by the regulator IC2 and IC3 If the voltage drops to a voltage that cannot be changed, the voltages V2 and V3 for the loads R2 and R3 decrease.
[0005]
The above operation will be described in detail with reference to FIGS.
When the load is sufficiently heavy, the current flowing through the choke coil L1 does not have a period of being cut off by the choke coil, so that a continuous mode as shown in FIG.
At this time, if the line impedance and the voltage drop due to the secondary-side rectifier diode are ignored, the current flowing through the choke coil L1 when the switching FET1 is on and the current flowing during the off time are equal.
(Equation 1)

Solving this for V1 gives
(Equation 2)

T = Ton + Toff V1: Output voltage (V)
VS1: Transformer T1 secondary winding voltage (V) Ton: FET1 on time (S)
Toff: FET1 off time (S)
Vin: Transformer primary side input voltage (V) f: Switching frequency (Hz)
NS1: number of turns on the secondary side of the transformer NP: number of turns on the primary side of the transformer From the equation (1), it can be seen that the output voltage V1 does not depend on the output current I1. Accordingly, when the load current is sufficiently large, the switching on time does not change even if the output current I1 changes, so that the pulse widths of the AC voltages VS2 and VS3 for the sub-power supply of the transformer T1 do not change, so that L2, L3 and C2, C3 The rectified and smoothed DC voltages V4 and V5 do not change, and V2 and V3 are stabilized by IC2 and IC3.
[0006]
On the other hand, when the load becomes lighter, a period occurs in which the current flowing through the choke coil L1 is cut off, so that a discontinuous mode is set as shown in FIG.
If the line impedance and the voltage drop due to the secondary-side rectifier diode are ignored, the current flowing through the choke coil L1 when the switching FET is on is equal to the current flowing during the off time,
[Equation 3]

Since the output current I1 is obtained by averaging the current waveforms in the discontinuous mode,
(Equation 4)

Solving this for V1 gives
(Equation 5)

L1: Secondary side choke coil inductance value (H) I1: Output current (A)
From the equation (2), it is understood that the output voltage V1 greatly depends on the output current I1. Therefore, when the load current is small, Ton is shortened and the output voltage V1 is controlled to be constant, so that the pulse widths of the sub-power supply AC voltages VS2 and VS3 of the transformer T1 are also narrowed, and L2, L3 and C2, C3 are used. The rectified and smoothed DC voltages V4 and V5 decrease, cannot be stabilized by IC2 and IC3, and V2 and V3 decrease.
[0007]
The cut-off current critical value Ir at which the output voltage V1 does not depend on the output current I1 is, as shown in FIG. 3B, the output current is the average of the current flowing through the choke coil L1.
(Equation 6)

It becomes.
[0008]
FIG. 4 shows the relationship between the output current I1 of the main power supply circuit and the output voltage V4 of the sub power supply circuit when the load on the main power supply circuit is heavy and light as described above.
When the load of the main power supply circuit is reduced and the output current I1 falls below the cutoff current critical value of the choke coil L1, the output voltage V4 of the sub-power supply circuit sharply drops as shown in FIG.
[0009]
The present invention solves such a conventional problem. The choke coils L1, L2, and L3 are combined choke coils to save space, and are directly controlled by the IC1 in the main power supply circuit. It is an object of the present invention to provide a multi-output switching power supply that improves output voltage of a sub-power supply circuit even when a load R1 of V1 changes to a state lighter than a cutoff current value of a choke coil.
[0010]
[Means for Solving the Problems]
An input power supply and a switch element are provided on the input side of the transformer, and a main output power supply circuit having a choke coil rectification circuit, and a constant current sub output power supply circuit also having a choke coil rectification circuit are provided on the output side of the transformer. Is provided, a forward converter type multiple output switching power supply device provided with a pulse width control circuit of a switch element for stabilizing the main output voltage by a feedback signal of the main output voltage of the output power supply circuit,
The choke coil of the main output power circuit and the choke coil of the sub output power circuit are composed of a composite choke coil wound around one core, and a current flows from the choke coil of the main output power circuit to the choke coil of the sub output power circuit. Make a way. Further, an element for supplying a current from the main output power supply circuit to the sub output power supply circuit may be provided. Further, only the element that supplies current from the main output power supply circuit to the sub output power supply circuit without using the composite choke coil is provided. By the means described above, a voltage drop of the sub power supply circuit is prevented even when the load of the main power supply circuit is reduced.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the description of the present embodiment, the same components as those of the circuit configuration of FIG. 2 are denoted by the same reference numerals, and redundant description will be omitted.
[0012]
FIG. 1 shows an embodiment of the present invention. The feature of this embodiment is that the choke coil is integrated.
[0013]
This is to employ a composite choke coil L10 in which a plurality of wires L10-1, L10-2, and L10-3 are wound around one core at the same winding ratio as the transformer.
The basic operation is the same as that of the conventional circuit shown in FIG. The difference is that the composite choke coil acts as a transformer, L10-1 is a primary winding, L10-2 and L10-3 are secondary windings, and current flows from the primary winding to the secondary winding. Even if the load on the main power supply circuit is reduced, the current flowing through the choke coil of the main power supply circuit is ensured to prevent a voltage drop of the sub-power supply circuit when the load is light.
[0014]
The operation will be described below.
In the case of the conventional choke coil, NS1 to I1 of T1 flowed to the load R1, NS2 to I2 of T1 flowed to the load R2, and NS3 to I3 of T1 flowed to the load R3.
In the case of the composite choke coil L10 of the present invention, the load R1 includes NS1 to I1 of T1, NS2 to I6 of T1 and L10-1 to I4 for the load R2, and NS3 to I7 and L10 of T1 for the load R3. I5 flows from -1.
Here, I2 = I4 + I6 I3 = I5 + I7.
On the other hand, the current flowing from the NS1 of T1 to the choke coil L10-1 is I1 + I4 + I5. When the current flowing through the choke coil L10-1 becomes equal to or less than the expression (3), V1 increases. To suppress this increase, the switching on time of the FET1 is controlled by the IC1. When the ON time is reduced, the pulse width of the AC voltage VS2 and VS3 for the auxiliary power supply of the transformer T1 becomes narrower, so that the DC voltages V4 and V5 rectified and smoothed by L2, L3 and C2 and C3 decrease, and are stabilized by the regulator IC2 and IC3 If the voltage drops to a voltage that cannot be changed, the voltages V2 and V3 for the loads R2 and R3 will drop.
Since the currents I4 and I5 flowing through the loads R2 and R3 are constant currents, even if the load R1 of the main power supply becomes a light load and the current I1 decreases, if the current I4 + I5 is more than the current shown in the above equation (3), V1 Does not increase, the switching on time of FET1 does not change, the pulse width of AC voltage VS2 and VS3 for the sub power supply of transformer T1 does not change, and DC voltage rectified and smoothed by L2, L3 and C2, C3. V4 and V5 do not change, and the voltages V2 and V3 for the loads R2 and R3 are stabilized.
[0015]
Another embodiment will be described below.
In this method, the resistors R4 and R5 indicated by broken lines are provided between the main power supply circuit and the sub power supply circuit in FIG. 1 to supply current from the main power supply circuit to the sub power supply circuit. In this case, the current flowing through the choke coil L10-1 becomes I4 + I5 + I6 + I7 in addition to I1 of the main power supply, and the voltage drop of the sub power supply circuit can be improved as in the above-described embodiment.
Also, the method of supplying current from the main power supply circuit to the sub-power supply circuit by attaching resistors R4 and R5 shown by broken lines between the main power supply circuit and the sub-power supply circuit by using L10 as a normal choke coil that is not a complex transformer type, The voltage drop of the circuit can be improved.
[0016]
In the above embodiment, two sub-power supply circuits have been described. However, the number of sub-power supply circuits is not limited to two and may be one or more sub-power supply circuits.
[0017]
【The invention's effect】
As described above, according to the present invention, space can be saved by using a composite choke coil, and a current flows from the main power choke coil to the sub power choke coil by using the choke coil as a transformer. Thus, it is possible to improve the occurrence of a voltage drop in the sub power supply circuit even when the load on the main power supply circuit is reduced.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a multiple output switching power supply device according to the present invention.
FIG. 2 is a diagram illustrating a conventional multi-output switching power supply device.
FIG. 3 is a current waveform of a choke coil L1.
FIG. 4 is a diagram showing a relationship between an output current of a main power supply circuit and an output voltage of a sub power supply circuit.
[Explanation of symbols]
Vin input voltage IC1 pulse control circuit FET1 switch element T1 transformer NP transformer primary winding number NS1, NS2, NS3 transformer secondary winding VS1, VS2, VS3 transformer secondary voltage CD1a, CD1b, CD2a, CD2b, CD3a, CD3b rectifying diode L1, L2, L3 Choke coil L10 Composite choke coil L10-1, L10-2, L10-3 Composite choke coil constituent coil V1, V2, V3 Load voltage V4, V5 Sub power supply circuit rectified output voltage C1, C2, C3 Capacitor IC1, IC2 Series regulator R1, R2, R3 Load R4, R5 Current supply element I1, I2, I3 Load current I4, I5 Supply current I6, I7 Sub-power supply circuit current I8, I9 Supply current

Claims (3)

An input power supply and a switch element are provided on the input side of the transformer, and a main output power supply circuit having a choke coil rectifier circuit, and a constant current auxiliary output power supply circuit also having a choke coil rectifier circuit are provided on the output side of the transformer. Wherein a pulse width control circuit of a switch element for stabilizing the main output voltage by a feedback signal of the output voltage of the main output power supply circuit is provided.
The choke coil of the main output power circuit and the choke coil of the sub output power circuit are composed of a composite choke coil wound around one core, and a current flows from the choke coil of the main output power circuit to the choke coil of the sub output power circuit. Multi-output switching power supply characterized by having a road 2. The multi-output switching power supply according to claim 1, further comprising an element for supplying a current from the main output power supply to the sub-output power supply. An input power supply and a switch element are provided on the input side of the transformer, and a main output power supply circuit having a choke coil rectifier circuit, and a constant current auxiliary output power supply circuit also having a choke coil rectifier circuit are provided on the output side of the transformer. Wherein a pulse width control circuit of a switch element for stabilizing the main output voltage by a feedback signal of the output voltage of the main output power supply circuit is provided.
A multi-output switching power supply device comprising an element for supplying a current from the main output power supply circuit to the sub output power supply circuit.

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