JPH07322601A - Switching regulator - Google Patents

Abstract

PURPOSE:To further increase a switching frequency by forming a ceramic capacitor of a ceramic capacitor single piece and a series connected body of a plurality of ceramic capacitors whose impedance at an electrostrictive resonance frequency is set to a specific value or less. CONSTITUTION:An input filter 1 is constituted as an L-type input filter for reducing input feedback terminal noise consisting of a choke coil 1a, a ceramic capacitor (single substance) 1b, and a ceramic capacitor series connected body 1c. Then, the number of input filters is determined so that the impedance of the entire ceramic capacitor series connection body 1c can be set at approximately 2OMEGA or less. In this case, since an input DC voltage is divided by the ceramic capacitor series connection body 1c, voltage applied to each of the ceramic capacitor can be suppressed to a voltage or less generated by electrostrictive resonance, thus effectively suppressing an input feedback terminal noise.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching regulator including an input feedback terminal noise reduction input filter as a constituent element.

[0002]

2. Description of the Related Art FIG. 3 shows a circuit configuration of an example of a switching regulator according to the prior art. In this case, the DC voltage V _{IN that} has passed through the input filter (consisting of the choke coil 1a and the capacitor 1b) 1 is applied to the primary winding of the transformer 3 in series with the primary winding. While the inserted switching element 2 is on / off controlled at a constant frequency, the DC voltage induced in the secondary winding of the transformer 3 is rectified by the rectifier circuit 4 and then smoothed by the smoothing circuit. In addition, it is supplied to a load (not shown). At that time, the smoothed DC voltage V
Depending on the deviation voltage between _O and the set voltage, the ON state pulse width in the switching element 2 is set to PW by the PWM control circuit 6.
By the M control, even if the state of the load fluctuates, the smoothed DC voltage V _O is obtained as a stabilized DC voltage of a desired voltage. When a ceramic capacitor for imposition is used as the capacitor 1b, the upper limit of the selectable capacitance is at most 1 μF. Therefore, when increasing the capacitance, the capacitors are connected in parallel as shown in the figure. It has become one.

Incidentally, in a switching regulator, a DC voltage is generally applied to a primary winding of a transformer through an input filter. A typical input filter used at that time is "a switching power supply Circuit design and mounting technology "(December 15, 1986, edited and published by Mimatsu Data System, page 386), the power supply impedance Zs is small and the load impedance is small in the line filter circuit configuration. A choke input L-type filter or a power supply impedance Zs which is effective in reducing the noise at the input feedback terminal under the condition that Z _R is large.
Load Inpi - it has become a dance Z _R [pi-type filter is effective to input feedback terminal noise reduction in both large conditions are used exclusively.

[0004]

By the way, in a switching regulator in general, input feedback terminal noise is generated due to a switching operation in a switching element. However, as the switching frequency becomes higher, The reality is that the presence of input feedback terminal noise cannot be ignored. To reduce the input feedback terminal noise, either set the inductance of the choke coil that makes up the input filter large, or set the capacitance of the capacitor large, or set both the inductance and capacitance large. It has been considered. However, when a ceramic capacitor is used as the capacitor, the DC input voltage is 2
Under the condition of 0 V to 30 V or less, the equivalent series resistance (ESR) characteristic of the ceramic capacitor alone shows an ideal characteristic as shown in FIG. 4, so the input feedback terminal noise is theoretical regardless of the switching frequency. The street is kept small. However, the DC input voltage is 20V
When the voltage is up to 30 V or more, the ESR characteristic of the ceramic capacitor alone becomes remarkably increased in a specific high frequency region as shown in FIG. That is, if the electrostrictive resonance frequency and the switching frequency match, the switching noise is not attenuated by the input filter and is fed back to the input side as it is as the input feedback terminal noise, causing malfunction or speech in other devices connected to the input side. That is, there is a possibility that noise or the like may be adversely affected. It should be noted that the electrostrictive resonance mentioned above means that 20 V is applied to the ceramic capacitor alone.
When a DC bias voltage of -30 V or more is applied,
As shown in FIG. 5, it is defined as a phenomenon that the equivalent series resistance remarkably increases at a frequency substantially higher than a specific frequency.

To summarize the problems in the conventional switching regulators in general, aluminum electrolytic capacitors or ceramic capacitors are exclusively used as capacitors as input filter components. Even if a ceramic capacitor is used, the switching frequency is at most 300k
Since it was relatively low below Hz, it did not match the electrostrictive resonance frequency (400 kHz or higher) of the ceramic capacitor, and it was not a particular problem. On the other hand, there is a strong demand for miniaturization of the switching regulator itself, and in order to meet this demand, it is indispensable to increase the switching frequency so that the input / output filter itself can be miniaturized. In other words, in the conventional switching regulator, when a ceramic capacitor is used as the capacitor of the input filter, the DC input voltage is higher than the critical voltage at which electrostrictive resonance occurs in the ceramic capacitor. If the switching frequency of the switching regulator and the electrostrictive resonance frequency of the ceramic capacitor match, the impedance of the filter itself will increase at that switching frequency.
For this reason, no consideration was given to the fact that the input feedback terminal noise reduction effect is necessarily suppressed to a low level.

As a countermeasure against the above problems, (1) the switching frequency of the switching regulator is changed so as not to match the electrostrictive resonance frequency of the ceramic capacitor used, and (2) the shape of the ceramic capacitor is changed. , Change it so that it does not match the switching frequency (electrostrictive resonance frequency of the ceramic capacitor can be estimated and changed by its W and L dimensions). (3) Hard coating around the ceramic capacitor so that the ceramic capacitor does not resonate. It is possible to do so. However, in the case of the method (1), the switching frequency must be made higher in consideration of the variation of the switching frequency and the variation of the electrostrictive resonance frequency. On the other hand, if the switching frequency becomes higher, the transformer, etc. Inevitably, the internal loss will increase, and in the case of the method of (2), the ceramic capacitor will be a custom product and the ceramic capacitor will be expensive, and in the method of (3), In terms of manufacturing, hard coating equipment is newly required. An object of the present invention is to provide a switching regulator capable of increasing the switching frequency while suppressing input feedback terminal noise, and further miniaturizing itself.

[0007]

SUMMARY OF THE INVENTION Basically, when the input feedback terminal noise reduction input filter as a constituent element is composed of a choke coil and a ceramic capacitor, the ceramic capacitor is
It consists of a single ceramic capacitor and a series connection body that has an impedance at the electrostrictive resonance frequency of about 2Ω or less and that consists of multiple ceramic capacitors, and these series connection body and the single ceramic capacitor are located near the choke coil. This is achieved by being configured as a predetermined arrangement.

[0008]

When the input DC voltage of 20 V or more is divided by connecting a plurality of ceramic capacitors in series, the DC voltage applied to each ceramic capacitor is below the critical voltage at which electrostrictive resonance occurs. It can be set. Therefore, when the input feedback terminal noise reduction input filter includes a series connection body consisting of a plurality of ceramic capacitors as its constituent elements, the result is that the impedance increase of the ceramic capacitors at the switching frequency of the switching regulator is suppressed. As a result, the input feedback terminal noise can be reduced.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to FIGS.
1 and 2 each show a circuit configuration of an example of a switching regulator according to the present invention, which includes an input feedback terminal noise reduction input filter having an input DC voltage of 20 V or more as a component.

First, the switching regulator shown in FIG. 1 will be described. The circuit configuration and operation of the switching regulator shown in FIG. 3 are the same except that the input feedback terminal noise is further reduced. Is almost the same as that of. That is, the input filter 1 itself has a characteristic. As shown in the figure, the input filter 1 is configured as an L-type input feedback terminal noise reduction input filter including a choke coil 1a, a ceramic capacitor (single unit) 1b, and a ceramic capacitor series connection body 1c. So far, the noise generated by the switching operation of the switching element 2 has been generated by the ceramic capacitor 1b and the choke coil 1b.
It appears as input feedback terminal noise on the input side as a state attenuated by a. At that time, the ceramic capacitor 1
When the electrostrictive resonance frequency of b matches the switching frequency, the input feedback terminal noise could not be sufficiently suppressed. However, as shown in the figure, a ceramic capacitor series connection body 1 in which a plurality of ceramic capacitors are connected in series to the ceramic capacitor 1b
When c is connected in parallel, the input DC voltage is divided by the ceramic capacitor series connection body 1c, so that the voltage applied to each ceramic capacitor is suppressed to the voltage at which electrostrictive resonance occurs or less. Since the increase in impedance of the ceramic capacitor at the switching frequency of the switching regulator is suppressed, the input feedback terminal noise can be effectively suppressed.

Next, the switching regulator shown in FIG. 2 will be described. As with the one shown in FIG. 1, the circuit configuration and the circuit operation are the same as those described above except that the input feedback terminal noise is further reduced. Is similar to that of the switching regulator shown in FIG. That is, the input filter 1 itself has a characteristic. As shown, the input filter 1 is a choke coil 1
a, a ceramic capacitor (single unit) 1b, and a ceramic capacitor series connection body 1c. As shown in the figure, the noise generated by the switching operation of the switching element 2 appears as input feedback terminal noise on the input side in a state of being attenuated by the ceramic capacitor 1b, the ceramic capacitor series connection body 1c and the choke coil 1a. In this case, as in the previous case, the input DC voltage is divided by the ceramic capacitor series connection body 1c, so that the voltage applied to each ceramic capacitor is suppressed to a voltage at which electrostrictive resonance occurs or less, and switching is performed. -The input feedback terminal noise can be efficiently suppressed since the impedance increase of the ceramic capacitor at the switching frequency of the regulator is suppressed. Even if the insertion positions of the ceramic capacitor 1b and the ceramic capacitor series connection body 1c are interchanged, the same effect can be obtained.

Incidentally, as a result of experimental confirmation, in order to reduce noise at the input feedback terminal, the impedance of the ceramic capacitor series-connected body 1c as a whole is 2Ω for the ceramic capacitor forming the ceramic capacitor series-connected body 1c.
When the number is decided to be set below the level,
It turned out that the effect was greatest.

[0013]

As described above, according to the first to third aspects, the switching frequency can be made higher while suppressing the input feedback terminal noise, and the switching itself can be made smaller. Each regulator is available.

[Brief description of drawings]

FIG. 1 is a diagram showing a circuit configuration of an example of a switching regulator according to the present invention including an input filter for reducing input feedback terminal noise as a component.

FIG. 2 is a diagram showing a circuit configuration of another example of the switching regulator according to the present invention, which includes an input filter for reducing input feedback terminal noise as a component.

FIG. 3 is a diagram showing a circuit configuration of an example of a switching regulator according to a conventional technique.

FIG. 4 is a diagram showing an ESR frequency characteristic when a DC bias voltage of 0 V is applied to a single ceramic capacitor.

FIG. 5 is a diagram showing ESR frequency characteristics when a DC bias voltage of 40 V is applied to a single ceramic capacitor.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Input filter, 1a ... Choke coil, 1b ... Ceramic capacitor, 2 ... Switching element, 3 ... Transformer, 4 ... Rectifier circuit, 5 ... Smoothing circuit, 6 ... PWM control circuit

Claims (3)

[Claims] 1. A switching element which is inserted in series with a transformer primary winding in a state in which a DC voltage that has passed through an input feedback terminal noise reduction input filter is applied to the transformer primary winding. ON at constant frequency above high frequency /
While being controlled to be off, the DC voltage induced in the secondary winding of the transformer is rectified and smoothed, and the ON state of the switching element is set according to the deviation voltage between the smoothed DC voltage and the set voltage. Is a switching regulator configured to be PWM controlled, and an input feedback terminal noise reduction input filter including a choke coil and a ceramic capacitor as constituent elements, a ceramic capacitor as a constituent element and a ceramic capacitor alone. , The impedance at the electrostrictive resonance frequency is set to about 2Ω or less, and is composed of a series connection body composed of a plurality of ceramic capacitors, and the series connection body and the ceramic capacitor unit are arranged in a predetermined manner near the choke coil. Switching configured as
regulator. 2. A switching element inserted in series in the transformer primary winding in a state where a DC voltage that has passed through an input feedback terminal noise reduction input filter is applied to the transformer primary winding. ON at constant frequency above high frequency /
While being controlled to be off, the DC voltage induced in the secondary winding of the transformer is rectified and smoothed, and the ON state of the switching element is set according to the deviation voltage between the smoothed DC voltage and the set voltage. Is a switching regulator configured to be PWM controlled, and an input feedback terminal noise reduction input filter including a choke coil and a ceramic capacitor as constituent elements, a ceramic capacitor as a constituent element and a ceramic capacitor alone. , The impedance at the electrostrictive resonance frequency is set to about 2Ω or less, and is composed of a series connection body composed of a plurality of ceramic capacitors, and the series connection body and the ceramic capacitor unit are both arranged on the rear side of the choke coil. Switching regulator configured as a closed state. 3. A switching element inserted in series in the transformer primary side winding in a state where a DC voltage that has passed through an input feedback terminal noise reduction input filter is applied to the transformer primary side winding. ON at constant frequency above high frequency /
While being controlled to be off, the DC voltage induced in the secondary winding of the transformer is rectified and smoothed, and the ON state of the switching element is set according to the deviation voltage between the smoothed DC voltage and the set voltage. Is a switching regulator configured to be PWM controlled, and an input feedback terminal noise reduction input filter including a choke coil and a ceramic capacitor as constituent elements, a ceramic capacitor as a constituent element and a ceramic capacitor alone. , An impedance at an electrostrictive resonance frequency is set to about 2Ω or less, and a series connection body composed of a plurality of ceramic capacitors is provided, and one of the series connection body and the ceramic capacitor alone is a choke. Assuming that the coil is placed on the front side and the other on the rear side of the choke coil Made is to have the switching regulator.