JPH066675Y2 - High frequency noise reduction device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Outline] A high-frequency noise reduction device for reducing high-frequency noise contained in an output terminal of an electronic device such as a power supply device. In order to reduce the number of mounting steps, the metal plate material for the anode that forms the anode output terminal is insulated and fixed to the housing, and the cathode output terminal is formed facing the metal plate material for the anode. The metal plate material is insulated and fixed to the housing, the dielectric film is arranged between the metal plate material for anode and the metal plate material for cathode, and further the metal plate material for anode, the metal plate material for cathode and the dielectric film between them. And the metal plate material for anode and the metal plate material for cathode are insulated and integrated with each other through the fixing means.

Insulating and fixing the anode metal plate material forming the anode output terminal to the housing, and insulatingly fixing the cathode metal plate material forming the cathode output terminal facing the anode metal plate material to the housing, An earth plate connected to the ground side is arranged between the anode metal plate material and the cathode metal plate material, and dielectric films are respectively arranged between the earth plate and the anode metal plate material and the cathode metal plate material, and , An anode metal plate material, a cathode metal plate material, a ground plate, and a dielectric film are integrally structured through fixing means in a state where the anode metal plate material, the cathode metal plate material, and the ground plate are insulated.

[Industrial application field]

The present invention relates to a high frequency noise reduction device that reduces high frequency noise contained in an output terminal of an electronic device such as a power supply device.

[Conventional technology]

BACKGROUND ART Electronic devices such as electronic calculators and integrated circuits that are required to operate at high speed use a power supply device that rectifies a commercial power supply and switches a transistor or the like to output a low voltage and large current. The output of this power supply device may contain high-frequency noise due to switching operation, and
There is a possibility of causing malfunction of the C circuit and the like.

Further, the same high frequency noise as described above may be included in the output from the electronic device such as the DC-DC converter.

As a countermeasure against such high frequency noise, a filter composed of a capacitor is attached to the output side of the electronic device to remove the high frequency noise.

As a high-frequency noise reduction device that removes such high-frequency noise, for example, a device disclosed in Japanese Utility Model Publication No. 62-27026 is known. This high frequency noise reduction device
A large number of capacitors are connected in parallel between the output terminal on the anode side and the output terminal on the cathode side of the switching power supply device, and high frequency noise is removed by these capacitors.

Further, high frequency noise reducing devices as shown in FIGS. 11 and 12 are also known.

In the figure, 61 is a switching type power supply device, and this switching type power supply device 61 has an anode side output terminal 62 and a cathode side output terminal 63, and these anode side output terminal 62 and cathode side output terminal 63 are a load 64. Connected to.

Reference numeral 65 denotes a housing, and a metal anode side output terminal block 66 and a metal cathode side output terminal block 67 are fixed to the mounting holes 65A and 65A of the housing 65 in an electrically insulated state. A metal plate material 68 for the anode is fixed to the output terminal block 66 on the anode side via screws 69. The metal plate 68 for the anode has legs 68A, and the legs 68A are fixed to the printed circuit board 70 by soldering or the like. A metal plate 71 for cathode is fixed to the cathode-side output terminal block 67 via screws 69. The metal plate 71 for cathode has legs 71A, which are fixed to the printed circuit board 70 by soldering or the like.

A capacitor C ₇ as a component is connected to the anode-side output terminal block 66 and the cathode-side output terminal block 67 via the lead wire 72, and the capacitor C ₇ aims to reduce high-frequency noise between both electrodes.

In addition, a large number of capacitors C ₈ as components are connected between the anode-side output terminal block 66 and the housing 65 on the ground side through the lead wires 73, and the capacitors C ₈ connect the anode-side output terminal 62 to the anode-side output terminal 62. High frequency noise is reduced between the ground and the ground.

Further, a large number of capacitors C ₉ as components are connected between the cathode-side output terminal block 67 and the housing 65 on the ground side through the lead wires 74, and the capacitors C ₉ connect the cathode-side output terminal 63 to the cathode-side output terminal 63. It is intended to reduce high frequency noise with the ground side.

[Problems to be solved by the device]

As described above, in the conventional high frequency noise reduction device, the lead wire 72 for connecting the capacitor C ₇ to the anode side output terminal block 66 and the cathode side output terminal block 67.
In need. Also, the anode side output terminal block 66
A lead wire 73 is required to connect a large number of capacitors C ₈ between the housing 65 on the ground side and the housing 65. further,
A lead wire 74 for connecting a large number of capacitors C ₉ between the cathode side output terminal block 67 and the housing 65 on the ground side.
In need.

However, as described above, the capacitors C ₇ and C as components are
_When high-frequency noise is contained in the outputs of the anode side output terminal 62 and the cathode side output terminal 63 of the structure in which ₈ and C ₉ are connected through the lead wires 72, 73 and 74, as shown in FIG. In terms of high frequency, the inductance L is generated by the lead wires 72, 73, 74, the impedance component also increases, the function as a filter for the capacitors C ₇ , C ₈ , C ₉ is diminished, and it is difficult to remove high frequency noise. was there.

Therefore, as shown in Japanese Utility Model Publication No. 62-27026, if the length of the lead wires 72, 73, 74 is shortened, the inductance L is also reduced, but it is still difficult to remove high frequency noise.

Further, since a large number of capacitors C ₇ , C ₈ and C ₉ are required, there is a problem that the number of mounting steps for those capacitors is large.

The present invention has been made to solve the above-mentioned problems, and an object thereof is to provide a high-frequency noise reduction device that reduces high-frequency noise by reducing the impedance in terms of high-frequency and facilitates removal of high-frequency noise. Is to provide.

[Means for Solving the Problem] In order to achieve the above-mentioned object, the invention according to claim 1 insulates and fixes a metal plate material for an anode forming an anode side output terminal to a housing, The cathode metal plate material that forms the cathode-side output terminal facing the plate material is insulated and fixed to the housing, and the dielectric film is arranged between the anode metal plate material and the cathode metal plate material. The plate member, the metal plate member for cathode, and the dielectric film between them are integrally structured through the fixing means in a state where the metal plate member for anode and the metal plate member for cathode are insulated.

Further, in the invention according to claim 2, the anode metal plate material forming the anode-side output terminal is insulated and fixed to the housing, and
The cathode metal plate material that forms the cathode side output terminal facing the anode metal plate material is insulated and fixed to the housing, and a ground plate connected to the ground side is provided between the anode metal plate material and the cathode metal plate material. A dielectric film is placed between the ground plate and the metal plate material for the anode and the metal plate material for the cathode, respectively, and further, the metal plate material for the anode, the metal plate material for the cathode, the ground plate and the dielectric film are used for the anode. The metal plate material, the metal plate material for the cathode, and the ground plate are integrated into one body through fixing means in an insulated state.

[Action]

According to the first aspect of the present invention, a capacitance is formed between the anode-side output terminal and the cathode-side output terminal by disposing a dielectric film between the anode metal plate material and the cathode metal plate material. .

According to the second aspect of the invention, a capacitance is formed between the anode side output terminal and the ground side by disposing a dielectric film between the anode metal plate and the ground plate. A capacitance is formed by disposing a dielectric film between the ground plate and the cathode metal plate between the ground side and the cathode side output terminal.

〔Example〕

 An embodiment of the present invention will be described below with reference to the drawings.

1 to 4 show a high frequency noise reducing apparatus according to a first embodiment of the present invention. In this embodiment, a case where this device is applied to a switching type power supply device will be described.

In FIG. 2, reference numeral 1 is a switching power supply device, and this switching power supply device 1 has an anode side output terminal 2 and a cathode side output terminal 3, and these anode side output terminals 2 and
The cathode side output terminal 3 is connected to the load 4.

In FIGS. 1 and 3, reference numeral 5 denotes a housing, and the mounting holes 5A and 5A of the housing 5 have metal-made output terminal block 6 on the anode side.
And the metal cathode-side output terminal block 7 is fixed in an electrically insulated state. Anode output terminal block 6
A metal plate material 8 for an anode is fixed to this via a screw 9. The anode metal plate member 8 has legs 8A, which are fixed to the printed circuit board 10 by soldering or the like. A metal plate material 11 for the cathode is fixed to the output terminal block 7 on the cathode side via screws 9. The cathode metal plate member 11 has legs 11A, and the legs 11A are fixed to the printed circuit board 10 by soldering or the like.

A dielectric film 12 made of mylar film is sandwiched between the anode metal plate member 8 and the cathode metal plate member 11, and these are integrally structured by fixing means 13 and 13. Details of the fixing means 13 are shown in FIG.

That is, a large diameter hole 8B is formed in the anode metal plate member 8, a large diameter hole 11B is formed in the cathode metal plate member 11, and a large diameter hole 12B is formed in the dielectric film 12. An insulating ring 14 is fitted in the large-diameter hole 8B of the anode metal plate member 8, and an insulating ring 15 is fitted in the large-diameter hole 11B of the cathode metal plate member 11, and a screw 16 penetrating the insulating rings 14 and 15 is fitted with a nut. The metal plate material 8 for anode, the metal plate material 11 for cathode and the dielectric film 12 are integrally structured by tightening with 17. Therefore, the fixing means 13 is composed of the insulating rings 14 and 15, the screw 16, and the nut 17, and the anode metal plate member 8 and the cathode metal plate member 11 are in an insulated state.

Thus, the metal plate 8 for anode and the output terminal block 6 on the anode side constitute the output terminal 2 on the anode side, and the metal plate 1 for cathode 1
1 and the cathode side output terminal block 7 includes the cathode side output terminal 3
Are configured.

At the same time, a capacitance C ₁ is formed between the anode output terminal 2 and the cathode output terminal 3 by disposing the dielectric film 12 between the anode metal plate 8 and the cathode metal plate 11. . High frequency noise between the electrodes is reduced by the capacitance C ₁ .

According to the above configuration, it becomes unnecessary to connect a capacitor as a conventional component between the anode side output terminal 2 and the cathode side output terminal 3, and the lead wire at the time of capacitor connection in terms of high frequency. Therefore, the inductance is not generated, the impedance component is reduced, the function of the electrostatic capacitance C _{1 as} a filter is improved, and the high frequency noise can be easily removed.

That is, since the large area of the metal plate material 8 for the anode of the output terminal 2 on the anode side and the metal plate material 11 for the cathode of the output terminal 3 on the cathode side can be used to configure both electrodes of the capacitance, a filter with low high-frequency impedance is formed. Will be done.

Further, unlike the conventional case, there is no need for a large number of capacitors as parts, and the number of mounting steps can be reduced.

5 to 8 show a high frequency noise reducing apparatus according to a second embodiment of the present invention.

In FIG. 6, 21 is a switching type power supply device, and this switching type power supply device 21 has an anode side output terminal 22 and a cathode side output terminal 23, and these anode side output terminal 22 and cathode side output terminal 23 are It is connected to the load 24.

In FIGS. 5 and 7, reference numeral 25 denotes a housing, and the housing 25
A metal anode side output terminal block 26 and a metal cathode side output terminal block 27 are fixed in the mounting holes 25A, 25A in an electrically insulated state. A metal plate material 28 for the anode is fixed to the output terminal block 26 on the anode side via screws 29. This anode metal plate 28 is a leg 2
8A, and the leg 28A is fixed to the printed circuit board 30 by soldering or the like. A cathode metal plate member 31 is fixed to the cathode-side output terminal block 27 via screws 29. The metal plate material 31 for the cathode has legs 31A, and the legs 31A
Is fixed to the printed circuit board 30 by soldering or the like.

Then, between the metal plate material for anode 28 and the metal plate material for cathode 31, a ground plate 32 connected to the housing 25 on the ground side is arranged. The ground plate 32 has a leg 32A and a leg 3A.
2A is fixed to the printed circuit board 30 by soldering or the like.

A dielectric film 33 made of a mylar film is sandwiched between the earth plate 32 and the metal plate member 28 for the anode, and a dielectric film 34 made of a mylar film is sandwiched between the earth plate 32 and the metal plate member 31 for the cathode.

The anode metal plate material 28, the cathode metal plate material 31, the ground plate 32, and the dielectric films 33 and 34 are fixed by the fixing means 35 while the anode metal plate material 28, the cathode metal plate material 31, and the ground plate 32 are insulated. , 35 to form an integrated structure. Details of the fixing means 35 are shown in FIG.

That is, the large diameter hole 28B is formed in the anode metal plate member 28, the large diameter hole 31B is formed in the cathode metal plate member 31, the large diameter hole 32B is formed in the ground plate 32, and the large diameter hole 33B is formed in the dielectric film 33.
However, large-diameter holes 34B are formed in the dielectric film 34, respectively. An insulating ring 36 is provided in the large-diameter hole 28B of the anode metal plate material 28, and a large-diameter hole 31B of the cathode metal plate material 31 is provided.
An insulating ring 37 is fitted in each of them, and a screw 38 penetrating the insulating rings 36 and 37 is tightened with a nut 39 to integrally form the anode metal plate member 28, the cathode metal plate member 31, and the dielectric films 33 and 34. Has been done. Therefore, the fixing means 35 described above is used for the insulating ring 3
6 and 37, screws 38, and nuts 39, the anode metal plate material 28, the cathode metal plate material 31, and the ground plate 32 are in an insulated state.

Then, the metal plate material 28 for anode and the anode side output terminal block 26 configure the anode side output terminal 22, and the metal plate material 31 for cathode and the cathode side output terminal block 27 configure the cathode side output terminal 23. .

At the same time, a dielectric film 33 is provided between the anode side output terminal 22 and the ground side, and between the anode metal plate 28 and the ground plate 32.
To form a capacitance C ₂ . Capacitance C
₂ reduces high frequency noise between the anode side output terminal 22 and the ground side.

Further, between the ground plate 32 and the cathode-side output terminal 23, a capacitance C ₃ is formed by disposing the dielectric film 34 between the ground plate 23 and the cathode metal plate material 31. Due to the capacitance C ₃ , high frequency noise between the cathode side output terminal 23 and the ground side is reduced.

According to the second embodiment, the same effect as the first embodiment can be obtained.

9 and 10 show a high frequency noise reducing apparatus according to a third embodiment of the present invention.

In the figure, 41 is a switching type power supply device, and this switching type power supply device 41 has an anode side output terminal 42 and a cathode side output terminal 43, and these anode side output terminal 42 and cathode side output terminal 43 are a load 44. Connected to.

Reference numeral 45 denotes a housing, and a metal plate material 46 for stepped anode and a metal plate material 47 for stepped cathode are fixed to the housing 45 in an electrically insulated state. Between the lower side of the stepped anode metal plate material 46 and the stepped cathode metal plate material 47, a ground plate 48 connected to the housing 45, which is the ground side, is arranged, and the ground plate 48 and the anode metal plate material 46 are connected to each other. The dielectric film 49 is sandwiched between the upper side and the dielectric plate 50 is sandwiched between the ground plate 48 and the upper side of the cathode metal plate member 47.

Further, the dielectric film 51 is sandwiched between the upper side of the stepped anode metal plate material 46 and the upper side between the stepped cathode metal plate materials 47.

The anode metal plate material 46, the cathode metal plate material 47, the ground plate 48, and the dielectric films 49, 50, 51 are fixed in a state where the anode metal plate material 46, the cathode metal plate material 47, and the ground plate 48 are insulated. It is integrally structured through means (not shown).

Then, the metal plate material 46 for the anode is connected to the anode side output terminal 42.
And the metal plate material 47 for the cathode constitutes the cathode side output terminal 43.
Are configured.

At the same time, a dielectric film 49 is provided between the anode side output terminal 42 and the ground side, and between the anode metal plate member 46 and the ground plate 48.
To form an electrostatic capacitance C ₄ . Capacitance C
₄ , the high frequency noise between the anode side output terminal 42 and the ground side is reduced. Also, ground side and cathode side output terminal 4
3, a capacitance C ₅ is formed by disposing a dielectric film 50 between the ground plate 48 and the cathode metal plate material 47. The electrostatic capacitance C ₅ reduces high frequency noise between the cathode side output terminal 43 and the ground side.

Further, between the anode side output terminal 42 and the cathode side output terminal 43, a capacitance C ₆ is formed by disposing a dielectric film 51 between the anode metal plate material 46 and the cathode metal plate material 47. . High frequency noise between the electrodes is reduced by the capacitance C ₆ .

A mylar film is used as the dielectric films 49, 50 and 51.

According to the third embodiment, the same effect as the first embodiment is obtained.

In addition, in the said Example, although a mylar film was mentioned as an example of a dielectric film, it is not limited to this.

Further, in the above embodiment, the screws and nuts are used as the fixing means for the metal plate material for the cathode, the ground plate and the dielectric film, but the invention is not limited to this.

[Effect of device]

As described above, according to the first aspect of the invention, the metal plate material for anode forms the output terminal on the anode side, and the metal plate material for cathode forms the output terminal on the cathode side. At the same time, an electrostatic capacitance is formed between the anode-side output terminal and the cathode-side output terminal by disposing a dielectric film between the anode metal plate material and the cathode metal plate material.

Therefore, it becomes unnecessary to connect a capacitor as a conventional component to the anode side output terminal and the cathode side output terminal,
In terms of high frequency, no inductance is generated by the lead wire when the capacitor is connected, the impedance component is reduced, the function of the electrostatic capacitance filter is improved, and high frequency noise can be easily removed.

That is, since both electrodes of electrostatic capacity can be constructed by utilizing the wide area of the metal plate material for anode of the output terminal on the anode side and the metal plate material for cathode of the output terminal on the cathode side, a filter with low high frequency impedance can be formed. Become.

Further, unlike the conventional case, it is possible to reduce the number of mounting steps without requiring a large number of capacitors as parts.

According to the second aspect of the present invention, a capacitance formed by disposing a dielectric film between the anode metal plate and the ground plate is formed between the anode output terminal and the ground side. The metal plate for the anode of the electrostatic capacity forms the anode side output terminal, and the earth plate of the electrostatic capacity constitutes the ground side.
Further, between the ground side and the cathode side output terminal, a capacitance is formed by disposing a dielectric film between the ground plate and the metal plate material for the cathode, and the ground plate of the capacitance is connected to the ground side. And the metal plate material for the cathode forms the cathode side output terminal.

Therefore, it is no longer necessary to connect a conventional capacitor between the anode side output terminal and the ground plate and between the ground plate and the cathode side output terminal. Can be easily removed.

[Brief description of drawings]

FIG. 1 is a perspective view of a high frequency noise reduction device according to a first embodiment of the present invention, FIG. 2 is an equivalent circuit diagram of the same high frequency noise reduction device, and FIG. 3 is an explanatory view of a longitudinal section of FIG. FIG. 4 is a sectional view taken along the line II-II of FIG. 1, FIG. 5 is a perspective view of a high frequency noise reducer according to a second embodiment of the present invention, and FIG. 6 is an equivalent circuit diagram of the same high frequency noise reducer. FIG. 8 is a vertical sectional view of FIG. 5, FIG. 8 is a sectional view taken along the line III-III of FIG. 5, and FIG. 9 is an equivalent circuit diagram of a high frequency noise reducing apparatus according to a third embodiment of the present invention. The figure is an explanatory view of the same high-frequency noise reduction device in a vertical section. Fig. 11 is a perspective view of a conventional high-frequency noise reduction device. Fig. 12 is an equivalent circuit diagram of the same high-frequency noise reduction device. Fig. 13 is the same high-frequency noise reduction device. It is explanatory drawing of the malfunction of an apparatus. In the figure, 2 is an output terminal on the anode side, 3 is an output terminal on the cathode side, 5 is a housing, 8 is a metal plate material for an anode, 11 is a metal plate material for a cathode, 12 is a dielectric film, and 13 is a fixing means.

Claims (2)

[Scope of utility model registration request] 1. A metal plate material for an anode forming an anode side output terminal is insulated and fixed to a housing, and a metal plate material for a cathode forming a cathode side output terminal facing the metal plate material for an anode is insulated from the housing. Then, a dielectric film is arranged between the metal plate material for the anode and the metal plate material for the cathode, and the metal plate material for the anode, the metal plate material for the cathode and the dielectric film between them are fixed to the metal for the anode. A high-frequency noise reduction device, characterized in that the plate material and the metal plate material for the cathode are integrally structured through a fixing means in an insulated state. 2. A metal plate material for an anode forming an anode side output terminal is insulated and fixed to a housing, and a metal plate material for a cathode facing the metal plate material for an anode and forming a cathode side output terminal is insulated to the housing. Then, dispose a ground plate connected to the ground side between the metal plate material for anode and the metal plate material for cathode, and dispose the dielectric film between the ground plate and the metal plate material for anode and the metal plate material for cathode, respectively. , And further, the metal plate material for the anode, the metal plate material for the cathode, the ground plate, the dielectric film,
A high-frequency noise reduction device characterized in that an anode metal plate material, a cathode metal plate material, and an earth plate are integrally structured through a fixing means in an insulated state.