JPH0611097B2 - Line filter - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a line filter that reduces so-called normal mode noise and common mode noise that occur when a switching power supply device is used.

[Technical Background of the Invention and Problems Thereof] Generally, when a switching power supply is used as a power supply device of an electronic device, so-called conduction noise is generated, but the conduction noise causes malfunction of the device.

Conducted noise is roughly classified into common mode noise (common mode noise) and normal mode noise (differential noise). Conventionally, in order to reduce these noises, a line filter as shown in FIG. 6 is switched. It was inserted before the power supply.

In FIG. 6, L _D1 and L _D2 are choke coils composed of two insulating coils, and L ₂ is a balun (balance-unbalance transformer) in which two coils are wound in one phase around a circular core.
, C _X1 and C _X2 are capacitors inserted between lines, and C _Y1 and C _Y2 are two capacitors inserted between the line and ground. Generally, a capacitor inserted between lines is called an X capacitor, and a capacitor inserted between a line and ground is called a Y capacitor.

In such a line filter, the insulating coil L
_D1 and L _D2 and the X capacitors C _X1 and C _X2 jointly remove normal mode noise generated between lines (hereinafter referred to as L to N), and the balun L ₂ and the Y capacitor C _Y1 are removed.
C _Y2 and is jointly, line - ground (below L / N~G
Common mode noise that occurs between

By the way, the normal mode noise is originally low in generation level and can be almost completely removed by increasing the capacitance of the X capacitors C _X1 and C _X2 , but the common mode noise is easily removed for the reason described below. Can not do it.

FIG. 7 is a diagram showing an equivalent circuit created for explaining the common mode noise in consideration of the noise source of the load and the equivalent impedance R of the input line.

In the figure, E _C is a voltage generated as a noise source, E _R
Indicates the noise voltage that actually appears between L / N and G.

The noise source voltage E _C is mainly generated by the potential fluctuation of the power transistor in the switching power supply device. When this voltage E _C is applied to the primary winding of the transformer (not shown) of the power supply device, the primary winding − noise current I _C flows to ground through the electrostatic capacitance C between the ground, the noise current I _C is returned to the switching power supply device through a portion of the line filter LF.

At this time, since the impedance R exists on the line input side of the switching power supply device, the noise voltage E _R
Appears. This noise voltage E _R is common mode noise.

The noise voltage E _R can be almost completely removed by increasing the inductance of the choke coil L ₂ and the capacitances of the Y capacitors C _Y1 and C _Y2. However, for safety reasons, the current I _C flowing to the ground is several. Since it must be suppressed to about mA, Y capacitors C _Y1 , C
The capacity of _Y2 necessarily has an upper limit value.

Therefore, it is necessary to increase the inductance of the coil L ₂ as much as possible to secure the required amount of attenuation. However, if the inductance of the coil L ₂ is increased, the size of the coil L ₂ is increased and the capacitance of the Y capacitor is increased. In comparison, the manufacturing cost also increases significantly.

Under such circumstances, it is not easy to remove the noise voltage E _R , that is, the common mode noise.

[Object of the Invention] The present invention has been made to solve the problems of the conventional line filter as described above, and suppresses the capacity of the Y capacitor to the upper limit value for safety measures, and further increases the size of the choke coil. It is an object of the present invention to provide a low-cost line filter capable of removing common mode noise without causing the above.

[Summary of the Invention] A line filter according to the present invention includes a first choke coil which is inserted on the line side on the input line side and is formed of a balun, and is inserted on the line side of a load side and is formed of a balun. A second choke coil, and a first Y inserted between a line on the output side of the first choke coil and the ground.
A capacitor, a first X capacitor inserted between the lines, a second Y capacitor inserted between the output side line of the second choke coil and the ground, and a line between them And a second X capacitor interposed between the switching power supply device and common mode noise generated from the switching power supply device are blocked by the inductances of the first and second choke coils and the first and second Y capacitors. It is characterized in that the normal mode noise generated from is blocked by the leakage inductances of the first and second choke coils and the first and second X capacitors.

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a circuit diagram showing an embodiment of the present invention. In the figure, L ₁ is a choke coil (hereinafter, simply referred to as balun) made of balun whose distributed capacitance is reduced by suppressing inductance, L ₂ is a balun having larger inductance than balun L ₁ , and C _X1 , C _X2 are L ~. X capacitors, C ₁ , C ₂ and C ₃ , C connected between N
Reference numeral ₄ denotes a Y capacitor inserted between L / N and G. The sum of the capacities of the Y capacitors C ₁ and C ₂ is set larger than the sum of the capacities of the Y capacitors C ₃ and C ₄ .

Then, for example, the line filter of the present embodiment is used as a line filter of a switching power supply device having a switching frequency of 50 kHz, and 100 dB with respect to 50 kHz noise
If you want to ensure the attenuation, _{L 1} = 2mH _L 1 of leakage inductance = 15μH L ₂ = 30mH L ₂ of the leakage inductance _{= 0.5mH C X1 = 0.3μF C X2} = 0.2μF C 1 = C ₂ = 9400 pF C ₃ = C ₄ = 4700 pF.

Next, the process leading to the construction of the line filter of this embodiment will be described.

Since the line filter of FIG. 1 includes both the X capacitor and the Y capacitor, it is possible to remove both normal mode noise and common mode noise. However, the common mode noise removal operation will be mainly described below. .

2 and 3 should be examined as to whether or not they are suitable as a filter circuit for removing common mode noise.
These are two types of filter circuits in which the Y capacitor C _Y has a different insertion position.

In each figure, E _C is a voltage generated as a noise source, E _R is a noise voltage actually appearing between L / N and G,
C is the capacitance between the primary winding of the transformer (not shown) of the power supply and ground, and R is the noise source and the equivalent impedance of the input line.

When the attenuation amount (IL) defined by IL = 20log ₁₀ (E _C / E _R ) [dB] is obtained for these two types of filter circuits, in the case of the filter circuit of FIG. Becomes

Note that ω ₀ represents the resonance frequency at which the attenuation decreases. Is required as.

On the other hand, in the case of the filter circuit of FIG. Becomes

The resonance frequency ω ₁ in this case is Is.

Then, the attenuation amount when ω = ω ₁ is It is represented by.

Next, the attenuation characteristics of the filter circuits shown in FIGS. 2 and 3 will be described with reference to FIG.

FIG. 4 is a graph showing the results of the relationship between the frequency and the attenuation of the filter circuit shown in FIGS. 2 and 3 obtained by the above formula, where D ₂ is the filter of FIG. The characteristic of the circuit, D ₃ shows the characteristic of the filter circuit of FIG.

Note that the calculation was performed with L ₂ = 30 mH C _Y = 28 nF C = 35 pF R = 50 Ω in each circuit.

As is apparent from this figure, when it is desired to secure the amount of attenuation at a relatively low frequency, the filter circuit of FIG. 2 is advantageous for the same choke coil L ₂ because the drop is smaller.

By the way, in the filter circuit shown in FIG. 2, when C _Y = 28 nF L ₂ = 30 mH is set, when the switching frequency is 50 kHz, 5
It is possible to secure 100 dB of attenuation for 0 kHz noise, but it is appropriate to use a balun as a choke coil with a relatively large inductance of 30 mH.

This is because the core of the balun does not saturate with respect to the differential current, and therefore a large inductance can be obtained with respect to the common-mode noise voltage when the load current is applied.
Since a balun having a large inductance has a large number of windings and a large distributed capacitance, it cannot serve as a choke coil in the high frequency band range of 1 MHz to 30 MHz, and as a result, the amount of attenuation may be reduced.

Therefore, the balun L ₁ is added as shown in FIG.

This balun L ₁ is a balun with suppressed inductance and reduced distributed capacitance.

And the attenuation amount IL of the filter circuit of FIG. Required by.

However, P = L ₁ / L ₂ Q = C _Y1 / C _Y2 S = C _Y2 / C A = [{(Q + 1) + (1 / S)} / Q {1+ (1 /
S)} + 1 / PQ] / 2 B = 1 / [PQ {1+ (1 / S)}] ω _R ² = 1 / L ₂ C _Y2 .

A specific attenuation amount IL at each frequency of the filter circuit of FIG. 5 is calculated by this calculation formula, and a combination of C _Y1 and C _Y2 that maximizes the attenuation amount at 50 kHz to 60 kHz is obtained, and L ₁ = 2 mH When L ₂ = 30 mH C = 35 pF R = 50Ω, C _Y1 = 18.8 nF C _Y2 = 9.4 nF was suitable under the condition of C _Y1 + C _Y2 = 28 nF.

In the above description, the sum of the Y capacitors C _Y1 and C _Y2 is 28,2 nF. However, since the commercially available capacitor elements do not have continuous capacitance values, this combination is the closest.

And in the above, if it replaced the balun _{L 1} and _{L 2,} when changing the capacitor _{C Y1} and _{C Y2} under the condition that _{L 1 = 30mH L 2 = 2mH} C Y1 + C Y2 = 28nF, in 50kHz~60kHz The attenuation amount of will drop considerably.

This is because if the inductance of the balun L ₁ is made considerably larger than that of L ₂ , a valley of the attenuation amount IL is created in the attenuation frequency band. Therefore, the inductance of balun L ₁ must be smaller than that of balun L ₂ .

From the above calculation results and facts, L ₁ = 2 mH L ₂ = 30 mH C _Y1 = 18.8 nF Therefore, C ₁ = C ₂ = 9400 pF C _Y2 = 9.4 nF Therefore, the condition of C ₃ = C ₄ = 4700 pF was found, The filter circuit of FIG. 1 was obtained.

When the filter circuit of this embodiment is connected to the primary coil side of the switching power supply, a smoothing capacitor is inserted in parallel on the primary coil side.

The capacities of the X capacitors C _X1 and C _X2 in this embodiment should be determined based on the capacity of this smoothing capacitor.

In this embodiment, C _X1 = 0.3 μF and C _X2 = 0.2 μF were set by the predetermined calculation formulas (described above).

In the filter circuit of this embodiment, the baluns L ₁ and L
If the leakage inductance of No. ₂ is increased, the normal mode noise can be sufficiently removed by the combination of this leakage inductance and the X capacitors C _X1 and C _X2 .

The leakage inductance of the balun should also be determined based on the capacity of the smoothing capacitor inserted on the primary coil side of the switching power supply, like the capacity of the X capacitor described above.

In this embodiment, the leakage inductance of L ₁ = ₁₅ μH and the leakage inductance of L ₂ = 0.5 mH are set based on a predetermined calculation formula (described above).

[Effects of the Invention] As described above, in the line filter of the present invention, the first choke coil interposed between the lines on the input side and the second choke coil interposed between the lines on the load side are provided. ,
A first Y capacitor inserted between the output side line of the first choke coil and the ground, a first X capacitor inserted between the lines, and an output side of the second choke coil. A second Y capacitor inserted between the line and the ground and a second X capacitor inserted between the lines, the first and second choke coils being provided. Are formed of baluns, and the inductance of the second choke coil is the first
Since it is bigger than that of the choke coil of
Common mode noise can be removed without increasing the size of the choke coil while keeping the capacity of the Y capacitor at the upper limit for safety measures.

[Brief description of drawings]

FIG. 1 is a diagram showing a circuit configuration of an embodiment of the present invention, and FIG.
FIGS. 3, 3 and 5 show an equivalent circuit used to derive the circuit of FIG. 1, and FIG. 4 shows FIGS. 2 and 3.
The graph which shows the attenuation characteristic of the circuit of the figure, FIG. 6 is a figure which shows the circuit structure of the conventional line filter, FIG. Is. L ₁ , L ₂ ... Choke coil C _X1 , C _X2 ... X capacitor C _Y1 , C _Y2 ... Y capacitor

Claims (3)

[Claims] 1. A first choke coil which is inserted on the line side of the input line side and is composed of a balun, and a second choke coil which is inserted on the line side of the load side and which is composed of a balun. A first Y capacitor inserted between a line on the output side of the first choke coil and the ground, a first X capacitor inserted between the lines, and a second Y capacitor of the second choke coil. A second Y capacitor inserted between the line on the output side and the ground and a second X capacitor inserted between the lines are provided to prevent common mode noise generated from the switching power supply device from being generated. The inductance of the first and second choke coils and the first
And a second Y capacitor, and normal mode noise generated from the switching power supply device is blocked by the leakage inductances of the first and second choke coils and the first and second X capacitors. . 2. The line filter according to claim 1, wherein the capacity of the first Y capacitor is larger than the capacity of the second Y capacitor. 3. The line filter according to claim 1, wherein the inductance of the second choke coil is larger than that of the first choke coil.