JP2011003471A - Switch device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switch device in which an effect of noises to a filter is controlled.SOLUTION: The switch device is provided with an antenna 70 which receives radio wave from the outside as an electric signal, an intermediate filter 75 which adjusts the frequency band of the electric signal received from the antenna 70, and a control circuit board on which the intermediate filter 75 is mounted. The switch device has a shield plate 60 installed to cover the intermediate filter 75 from both sides of the plate thickness direction of the control circuit board, and the shield plate 60 is constructed of a single member.

Description

  The present invention includes a receiving unit that receives a radio wave as an electrical signal from the outside, a filter that adjusts the frequency band of the electrical signal received by the receiving unit, and a circuit board on which the filter is mounted, and is based on the radio wave. The present invention relates to a switch device in which a load is controlled.

  As the switch device, there is known a device that controls the on state and the off state of a load such as an illumination load by receiving a radio wave transmitted from an operation terminal that remotely operates the switch device. The received radio wave is adjusted to a predetermined frequency band as an electric signal by a filter, converted into a digital signal, and input to the microcomputer. The microcomputer controls the on and off states of the load based on this digital signal (see, for example, Patent Document 1).

JP 2005-38795 A

  By the way, filters tend to be more susceptible to noise than other electronic components, so when the filter is affected by noise, the filter can adjust the electrical signal to a predetermined frequency band. In some cases, a frequency band different from the above frequency band may be input to the microcomputer. As a result, there is a possibility that the switch device malfunctions due to erroneous detection by the microcomputer.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a switch device in which the influence of noise on the filter is suppressed.

In the following, means for achieving the above object and its effects are described.
(1) The invention described in claim 1 is a receiving unit that receives a radio wave from the outside and converts the radio wave into an electric signal, a filter that adjusts a frequency band of the electric signal received by the receiving unit, and the filter In the switch device in which the load is controlled based on the electrical signal, the switch device is provided with a shield plate that covers the filter from both sides in the plate thickness direction of the circuit board. The gist of the shield plate is a single member.

  According to this invention, it becomes possible to suppress the influence of noise on the filter by providing the shield plate on the filter. Further, by covering the filter from both sides in the plate thickness direction of the circuit board, the surface covering the filter is increased, so that the influence of noise on the filter is suppressed compared to the case of covering one side of the filter in the plate thickness direction. The effect can be further improved.

  In addition, since the shield plate is formed as a single member, for example, the number of parts as a whole switch device can be reduced as compared with a case where the shield plate is composed of a plurality of members. Therefore, the cost of the switch device can be reduced.

  (2) The invention according to claim 2 is the switch device according to claim 1, wherein the shield plate includes a first cover portion that covers the filter from one side in the plate thickness direction, and a plate in the plate thickness direction. A second cover portion that covers the filter from the other side via the circuit board; and a connecting portion that connects the first cover portion and the second cover portion in the plate thickness direction. The gist is that the circuit board is arranged outside the outer peripheral edge of the circuit board.

  According to the present invention, the connecting portion is disposed outside the outer peripheral edge of the circuit board, so that a through hole for inserting the communication portion into the circuit board can be omitted. Therefore, in the circuit board, it is possible to suppress a reduction in a space for mounting electronic components and a space for forming a wiring pattern.

(3) The invention according to claim 3 is summarized in that, in the switch device according to claim 2, the first cover portion is provided with a side surface cover portion that covers the side surface of the filter.
According to this invention, since the range which a shield board covers a filter increases by covering the side surface of a filter with a side surface cover part, the influence of the noise to a filter can be suppressed further.

  (4) According to a fourth aspect of the present invention, in the switch device according to any one of the first to third aspects, the circuit board is recessed in one direction perpendicular to the plate thickness direction. A circuit board side engaging portion is provided, and the shield plate is provided with a shield plate side engaging portion that is recessed in a direction opposite to the one direction, and the shield plate is located on the one side with respect to the circuit board. The gist is that the circuit board side engaging portion and the shield plate side engaging portion are engaged with each other by being inserted in the direction.

  According to the present invention, the shield plate is attached to the circuit board by being inserted in one direction perpendicular to the thickness direction with respect to the circuit board. Compared to the case of attaching the shield plate, the shield plate and the circuit board can be easily assembled.

(5) The invention according to claim 5 is the switch device according to claim 4, wherein the circuit board side engaging portion is provided on an outer peripheral edge of the circuit board.
According to this invention, compared with the case where the circuit board side engaging portion is provided at the center of the circuit board, it does not hinder the mounting of the electronic component and the formation of the wiring pattern. The degree of freedom of setting can be improved.

(6) The invention according to claim 6 is the switch device according to claim 4 or 5, wherein the filter is mounted close to the circuit board side engaging portion.
According to this invention, the filter is mounted close to the circuit board side engaging portion, thereby reducing the size of the shield plate compared to the case where the filter is mounted away from the circuit board side engaging portion. Will be able to. Therefore, the metal plate forming the shield plate can be made small, so that the material cost of the shield plate can be reduced.

  (7) The invention according to claim 7 corresponds to the first side surface of the switch device according to claim 3, which is not covered by the side surface cover portion and the connecting portion on the side surface of the filter. The distance from the outer peripheral edge of the first cover part is larger than the distance between the second side face covered by the side cover part and the connecting part and the outer peripheral edge of the first cover part corresponding to the second side face. The gist is that it is formed.

  According to this invention, the outer periphery of the first cover portion corresponding to the first side surface that is not covered by the side surface cover portion and the connecting portion is outside the first cover portion corresponding to the second side surface that is a side surface other than the first side surface. Since it is formed so as to extend beyond the peripheral edge, the influence of noise entering from the first side surface on the filter can be suppressed.

  (8) The invention according to claim 8 is the switch device according to any one of claims 1 to 7, wherein the shield plate is electrically connected to a ground portion serving as a reference potential of the circuit board. The gist is to be connected.

  According to the present invention, since the equipotential surface is formed in the space surrounded by the shield plate by electrically connecting the shield plate to the ground portion, the shield plate further suppresses the influence of noise on the filter. Will be able to.

  (9) The invention according to claim 9 is the switch device according to any one of claims 1 to 8, wherein the circuit board amplifies the frequency band of the electric signal adjusted by the filter. An amplifier circuit is provided, and the shield plate covers the amplifier circuit.

  According to the present invention, the shield plate covers the amplifier circuit in addition to the filter, so that the influence of noise on the amplifier circuit can be suppressed. Therefore, the influence of noise on the frequency band adjusted by the filter is further reduced.

  (10) The switch device according to claim 9, wherein the amplifier circuit is a surface opposite to the surface of the circuit board on which the filter is mounted in the plate thickness direction. The gist is that it is formed.

  According to the present invention, since the amplifier circuit is formed on the side of the circuit board opposite to the filter, the amplifier circuit can be formed without depending on the shield plate. Therefore, the degree of freedom in forming the amplifier circuit on the circuit board is improved.

  ADVANTAGE OF THE INVENTION According to this invention, the switch apparatus which suppressed the influence of the noise to a filter can be provided.

BRIEF DESCRIPTION OF THE DRAWINGS Schematic which shows the load control system of the structure to which the switch apparatus is applied about one Embodiment which actualized the switch apparatus of this invention. The disassembled perspective view which shows the disassembled perspective structure of the switch apparatus of the embodiment. Sectional drawing which shows the cross-section of the switch apparatus of the embodiment. The block diagram of the load control part of a control circuit board | substrate about the switch apparatus of the embodiment. 4A is a perspective view showing a perspective structure of the front surface of the control circuit board, and FIG. 5B is a perspective view showing a perspective structure of the back surface of the control circuit board. The perspective view which shows the perspective structure of a shield board about the switch apparatus of the embodiment. Regarding the switch device of the embodiment, (a) a front view showing the front structure of the shield plate, (b) a plan view showing the planar structure of the shield plate, (c) a bottom view showing the lower surface structure of the shield plate, (d). The side view which shows the side structure of a shield board. Regarding the switch device of the same embodiment, (a) a plan view showing a planar structure of the surface of the control circuit board in a state where the shield plate is attached to the control circuit board, (b) a side structure in the width direction of the control circuit board The side view which shows, (c) The side view which shows the side structure of the perpendicular direction of the control circuit board. Regarding the switch device of the embodiment, (a) a plan view showing a planar structure of the back surface of the control circuit board in a state where the shield plate is attached to the control circuit board, and (b) a side structure in the vertical direction of the control circuit board. FIG. In the switch device of the embodiment, (a) a perspective view showing a perspective structure in a state in which the control circuit board and the shield plate are separated from each other, (b) a perspective structure in a state in which the control circuit board and the shield plate are engaged. FIG. About the switch device of the embodiment, (a) an enlarged view showing a state where the circuit board side engaging portion and the shield plate side engaging portion are separated from each other, (b) the circuit board side engaging portion and the shield plate side engaging portion. The enlarged view which shows the state which the part mutually engaged. Sectional drawing which shows the side structure of the state by which the shield board was attached to the control circuit board about other embodiment which actualized the switch apparatus of this invention.

  With reference to FIGS. 1-11, one Embodiment which actualized the switch apparatus of this invention as a switch apparatus which switches the ON state and OFF state of the load (henceforth "lighting load L") of a lighting fixture is described. FIG. 1 shows an outline of a load control system for a construction product to which the switch device is applied.

  As shown in FIG. 1, an interphone system is configured among fire alarm devices 2 </ b> A to 2 </ b> C that detect a fire when a fire is detected, an operation terminal device 3 for remotely operating a lighting load L, and an interphone slave unit 5. A wireless signal transmitted from the intercom base unit 4 is transmitted to the switch device 1. And the switch apparatus 1 is lighting or extinguishing the illumination load L by switching the supply state and interruption | blocking state of the electric power supply of commercial power supply AC according to the received wireless signal. Here, when the switch device 1 is in the on state, the commercial power supply AC is in the supply state, so that the lighting load L is lit. When the switch device 1 is in the off state, the commercial power source AC is in the cut-off state. L comes off.

  Here, the switch apparatus 1 is provided on the wall surface of the construction material which comprises the predetermined | prescribed room of constructions, such as a house, for example. The fire alarms 2A to 2C are respectively installed in the predetermined room and a room other than the predetermined room. The operation terminal 3 is arranged in a predetermined room. The interphone master unit 4 is installed in a predetermined room, and the interphone slave unit 5 is installed on a gate pillar provided outside the construction, for example.

  In addition, as a wireless signal, radio waves are transmitted in accordance with “specified low-power radio stations for telemeters, telecontrols and data transmissions” prescribed in Article 6, Paragraph 2, Item 2 of the Radio Law Enforcement Regulations. It is what. By using radio waves as a wireless signal, the fire alarms 2B and 2C and the intercom cordless handset 5 installed outside the predetermined room where the switch device 1 is installed can be connected without direct cable connection. Sending and receiving can be performed.

Next, the configuration of the switch device 1 will be described with reference to FIGS. 2 and 3.
As shown in FIG. 2, the switch device 1 controls an illumination load L, a switch main body portion 1A that constitutes an outer frame and is fixed to a wall surface, a terminal portion 1B that is connected to an electric wire wired in the construction material. Circuit part 1C which performs, and operation part 1D which switches the ON state and OFF state of illumination load L by pushing operation. In addition, the switch device 1 is provided with an indicator lamp 1E made of a light emitting diode that displays an on state and an off state, respectively. The indicator lamp 1E is turned off when the switch device 1 is in an on state, and is turned on when the switch device 1 is in an off state. Thereby, when the room is dark with the illumination load L turned off, the user can recognize the position of the switch device 1 by the indicator lamp 1E.

  Hereinafter, the longitudinal direction of the switch body 1A is referred to as “vertical direction”, the short direction of the switch body 1A is referred to as “width direction”, and the direction orthogonal to both the vertical direction and the width direction is referred to as “depth direction”. To do. In the depth direction, the side on which the operation unit 1D is arranged is referred to as “front side”, and the side on which the terminal unit 1B is arranged is referred to as “back side”.

  The switch main body 1A is provided with an attachment frame 10 fixed to the construction material. A body 11 is disposed on the far side in the depth direction from the mounting frame 10. An intermediate cover 12 that covers the body 11 from the surface side in the depth direction is attached to the body 11. The intermediate cover 12 is attached to the attachment frame 10. As a result, the body 11 is attached to the attachment frame 10 via the intermediate cover 12.

  The mounting frame 10 is configured as a frame having an opening hole in the center. The mounting frame 10 is provided with a first fixing portion 10b for fixing to the wall surface and a second fixing portion 10c for fixing the intermediate cover 12. The 1st fixing | fixed part 10b is provided in a pair of edge | side along the width direction of a frame. The second fixing portion 10c is connected to the first fixing portion 10b and is provided on a pair of sides along the vertical direction.

  The body 11 is provided with a peripheral wall portion 11 a and a bottom wall portion 11 b that constitute an outer frame of the body 11. Thereby, the body 11 is comprised by the concave shape which opens the surface side of a depth direction. Inside the body 11, there are provided a terminal accommodating portion 11c for accommodating the terminal portion 1B and an electronic component accommodating portion 11d for accommodating electronic components of the circuit portion 1C.

  The intermediate cover 12 is provided with an operation button 12a for transmitting a pressing operation from the operation unit 1D to the circuit unit 1C at a central portion in the vertical direction of the intermediate cover 12. The outer edge of the intermediate cover 12 is provided with an attachment frame fixing portion 12b for fixing to the second fixing portion 10c in the width direction and a body fixing portion 12c for fixing to the body 11 in the vertical direction. Yes.

  The terminal portion 1B is configured in such a manner that the release button 20, the pair of lock springs 21, and the pair of terminal plates 22 are housed in order from the rear surface side in the depth direction toward the front surface side in the terminal housing portion 11c. As a result, the pair of electric wires inserted through the two insertion portions (not shown) that are through holes for inserting the electric wires provided in the bottom wall portion 11b of the body 11 are the lock spring 21 and the terminal plate. And 22 respectively. The switch device 1 switches between a power supply state and a cut-off state between a pair of electric wires by switching a power supply state (on state) and a cut-off state (off state) between the pair of terminal plates 22.

  The circuit unit 1 </ b> C includes a control circuit board 30 disposed on the back surface side in the depth direction from the intermediate cover 12 and a power circuit board 40 disposed on the back surface side in the depth direction from the control circuit board 30. The control circuit board 30 is housed in the intermediate cover 12 and attached to the intermediate cover 12. The power circuit board 40 is accommodated in the body 11 so as to cover the terminal accommodating portion 11c and the electronic component accommodating portion 11d. Further, the control circuit board 30 and the power supply circuit board 40 are electrically connected to each other by a connector 33 and a connector 45 (see FIG. 3).

  The control circuit board 30 is provided with a load control unit 30 </ b> A that receives radio waves from the fire alarm devices 2 </ b> A to 2 </ b> C, the operation terminal device 3, and the intercom slave device 5 and controls the illumination load L. Further, the control circuit board 30 is provided with a push button switch 34 that can be switched between an on state and an off state of the switch device 1 in accordance with a pressing operation of the operation unit 1D.

  The power supply circuit board 40 is provided with a printed wiring board 41 on which a wiring pattern (not shown) is formed. A terminal board 22 is connected to the printed wiring board 41. Further, a transistor 42 and a heat radiating plate 43 that contacts the transistor 42 and radiates the heat of the transistor 42 are connected to the printed wiring board 41 corresponding to the electronic component housing portion 11d. The transistor 42 and the heat radiating plate 43 are accommodated in the electronic component accommodating portion 11d.

  An insulating plate 44 formed in a plate shape using a resin material having electrical insulation is disposed between the control circuit board 30 and the power circuit board 40 in the vertical direction. This avoids electrical continuity between the control circuit board 30 and the power supply circuit board 40 except for the connectors 33 and 45.

  The operation unit 1D includes an operation handle 50 that is directly pressed by the user, and a leaf spring 51 that returns from the pressing operation of the operation handle 50. The leaf spring 51 is attached to a spring attachment portion (not shown) provided on one end side in the width direction of the intermediate cover 12. Further, on the other end side in the width direction of the operation handle 50, a locking claw 50a (see FIG. 3) that locks with a locking hole (not shown) provided in the intermediate cover 12 is provided. Thereby, the amount by which the operation handle 50 moves from the intermediate cover 12 to the surface side in the depth direction is regulated. Further, the operation handle 50 is provided with a window hole 50b for exposing the indicator lamp 1E at one end side in the width direction of the operation handle 50 and at the center in the vertical direction.

  As shown in FIG. 3, the push button switch 34 of the control circuit board 30 is arranged on the back side in the depth direction of the operation button 12 a of the intermediate cover 12. When the user presses the operation handle 50, the operation handle 50 presses the operation button 12a. When the operation button 12a is pressed, the operation button 12a presses the push button switch 34. Accordingly, the push button switch 34 is switched from the off state to the on state or from the on state to the off state.

Next, details of the control circuit board 30 will be described with reference to FIGS. 4 and 5.
As shown in FIG. 4, the control circuit board 30 controls the on and off states of the switch device 1 from radio waves from the fire alarm devices 2A to 2C, the operation terminal 3 and the interphone slave unit 5 (see FIG. 1). A load control unit 30A is provided. The load control unit 30A includes an antenna 70, an RF filter 71, a vibrator 72, a local filter 73, a mixer unit 74, an intermediate filter 75, an amplifier circuit 76, a demodulation unit 77, and a microcomputer 78. It is comprised by.

  The antenna 70 constitutes a receiving unit that receives radio waves from the fire alarm devices 2A to 2C, the operation terminal device 3, and the intercom slave device 5 as electrical signals. The RF filter 71 adjusts the frequency band of the electric signal from the antenna 70. The vibrator 72 generates an electrical signal in a predetermined frequency band set in advance. The local filter 73 adjusts the frequency band of the electrical signal of the vibrator 72. The mixer unit 74 generates an electric signal in a predetermined frequency band from the frequency band of the electric signal between the antenna 70 and the vibrator 72. The intermediate filter 75 adjusts the frequency band of the electric signal from the mixer unit 74. The amplifier circuit 76 amplifies the amplitude of the electric signal from the intermediate filter 75. The demodulator 77 is constituted by, for example, an FMIC, and converts an electrical signal into a digital signal. The microcomputer 78 controls the on state and the off state of the switch device 1 based on the digital signal.

  Specifically, the radio wave received by the antenna 70 is adjusted to a frequency band of, for example, around 426.11 MHz by the RF filter 71 as a sine wave analog electric signal. On the other hand, a sine wave analog electric signal having a predetermined frequency band is formed in the vibrator 72, and the electric signal is adjusted by a local filter 73 to a frequency band around 426.5 MHz, for example. Then, the electric signal adjusted by the RF filter 71 and the local filter 73 is generated by the mixer unit 74 as an electric signal having a frequency band around 455 KHz necessary for the load control unit 30A. The electrical signal generated by the mixer unit 74 is adjusted to a 455 KHz electrical signal by the intermediate filter 75 and input to the amplifier circuit 76. In the amplifier circuit 76, the amplitude of the electric signal is converted into an amplified electric signal and input to the demodulator 77. In the demodulator 77, the analog electrical signal is converted into a digital electrical signal and input to the microcomputer 78.

  As shown in FIG. 5, the control circuit board 30 includes an electronic component group constituting the load control unit 30 </ b> A, a connector 33, and a push button switch 34 on a printed wiring board 32 formed in a substantially rectangular shape that is slightly longer in the vertical direction. And have been implemented. The electronic component group is mounted on both surfaces in the depth direction (plate thickness direction) of the front surface and the back surface of the printed wiring board 32.

  An intermediate filter 75 is mounted on the end of the printed wiring board 32 on the lower side in the vertical direction and on the other end side in the width direction. On both sides in the width direction of the intermediate filter 75 in the printed wiring board 32, concave circuit board side engaging portions that penetrate in the thickness direction (that is, the depth direction) of the printed wiring board 32 and are recessed upward in the vertical direction. 32a is provided.

  Further, on one side 32b of the outer peripheral edge at the lower end in the vertical direction of the printed wiring board 32 where the circuit board side engaging portions 32a are formed, the outside of the filter mounting portion 32c sandwiched between the circuit board side engaging portions 32a in the width direction. The peripheral edge is provided above the other side 32b of the outer peripheral edge in the vertical direction. Accordingly, the printed wiring board 32 is formed with a recess 32b1 that is recessed upward in the vertical direction. Further, a first inclined portion 32 d that is inclined downward in the vertical direction and in the width direction is provided at a connection portion between the circuit board side engaging portion 32 a and one side 32 b of the outer peripheral edge of the printed wiring board 32.

  When the connector 33 is mounted on the outer peripheral edge of the printed wiring board 32, that is, at the center portion in the vertical direction and the other end side in the width direction of the printed wiring board 32, lead wires (not connected) connected to the connector 33 are connected. A concave insertion portion 32e is provided for insertion of the insertion portion.

  In addition, a notch 32 f is provided at the end on the other end side in the width direction on one side 32 b of the outer peripheral edge of the printed wiring board 32. Between the vertical direction of this notch 32f and the insertion part 32e, the protrusion part 32g which comprises both these notch 32f and the insertion part 32e is provided. Further, a second inclined portion that is inclined downward in the vertical direction is formed at a connecting portion between one side of the outer peripheral edge of the printed wiring board 32 constituting the cutout portion 32f and one side 32b of the outer peripheral edge of the printed wiring board 32. An inclined portion 32h is provided.

The electronic component group constituting the load control unit 30A is mounted on the front surface and the back surface of the control circuit board 30 as follows. Note that the mixer unit 74 is omitted.
As shown in FIG. 5A, the antenna 70, the intermediate filter 75, and the microcomputer 78 are mounted on the surface of the control circuit board 30. The antenna 70 is mounted on the upper end of the printed wiring board 32 in the vertical direction. The microcomputer 78 is mounted at the center of the printed wiring board 32.

  As shown in FIG. 5B, on the back surface of the control circuit board 30, an RF filter 71, a vibrator 72, a local filter 73, an amplifier circuit 76 (shaded area portion in FIG. 5B), and a demodulator 77 are provided. And have been implemented. In particular, the amplifier circuit 76 is formed at the lower end of the printed wiring board 32 in the vertical direction and the other end of the width direction.

  A connector 33 and a push button switch 34 are mounted on the surface of the control circuit board 30 (see FIG. 5A). The push button switch 34 is mounted at a position corresponding to the operation button 12 a of the intermediate cover 12 in the central portion of the printed wiring board 32.

Next, the details of the shield plate 60 attached to the control circuit board 30 will be described with reference to FIGS. 6 and 7.
As shown in FIG. 6, the shield plate 60 is formed by bending a single member metal plate such as press working. The shield plate 60 includes a first cover portion 61 that covers the surface of the control circuit board 30 (see FIG. 5A) and a second cover portion that covers the back surface of the control circuit board 30 (see FIG. 5B). 62 and a connecting portion 63 that connects the first cover portion 61 and the second cover portion 62 are provided. The first cover part 61 and the second cover part 62 are formed in parallel to each other and are provided so as to extend upward in the vertical direction from the connecting part 63. The connecting portion 63 is provided so as to extend along the depth direction.

  The 1st cover part 61 is formed in the substantially rectangular shape from which a vertical direction is long and a width direction is short (refer FIG.7 (b)). Side cover parts 64 formed by bending from the first cover part 61 toward the back side in the depth direction are provided on both sides of the first cover part 61 in the width direction. The side cover portion 64 is formed so as to extend along the depth direction and the vertical direction (see FIG. 7D). Further, the first cover part 61 is formed so as to extend upward in the vertical direction from the side cover part 64.

  A shield plate side engagement portion 64 a that engages with the control circuit board 30 is provided on the back surface side of each side cover portion 64 in the depth direction. The shield plate side engaging portion 64a has a first portion 64a1 extending from the rear surface side end portion 64b of the side surface cover portion 64 in the depth direction to the back surface side, and extends upward from the first portion 64a1 in the vertical direction. A second portion 64a2 is provided. The shield plate side engaging portion 64a is formed in a concave shape that is recessed downward in the vertical direction by the end portion 64b of the side surface cover portion 64, the first portion 64a1, and the second portion 64a2.

  Moreover, the 1st inclination part 64c which inclines to the surface side of a depth direction as it goes to the upper direction of a perpendicular direction is provided in the edge part of the back surface side of the vertical direction of each side surface cover part 64 in the depth direction. ing. In addition, an inclined portion 64a3 that is inclined toward the back side in the depth direction as it goes downward in the vertical direction is provided at the upper end portion of the second portion 64a2 in the vertical direction.

  The second cover portion 62 is provided with a facing portion 62a that faces the first cover portion 61 in the depth direction, and an extension portion 62b that extends upward in the width direction and the vertical direction from the facing portion 62a (FIG. 7). (See (c)).

  At the end in the width direction of the second cover portion 62, that is, the end in the width direction of the extension portion 62b, a side end portion 62b1 formed by being bent from the same end portion to the surface side in the depth direction is provided. . A shield plate side engaging portion 62c is provided at the side end portion 62b1. The shield plate side engaging portion 62c includes a first portion 62c1 extending from the lower end portion in the vertical direction to the front surface side in the depth direction at the end portion 62b2 on the surface side in the depth direction of the side end portion 62b1, and the first portion 62c1. A second part 62c2 extending upward in the vertical direction from the part 62c1 is provided. The shield plate side engaging portion 62c is formed in a concave shape that is recessed downward in the vertical direction by the end portion 62b2 of the side end portion 62b1, the first portion 62c1, and the second portion 62c2.

  A second inclined portion 62b3 that is inclined toward the back surface side in the depth direction as it goes upward in the vertical direction is provided at the end portion on the upper side in the vertical direction of the side end portion 62b1 and the end portion on the front surface side in the depth direction. . In addition, an inclined portion 62c3 that inclines toward the surface side in the depth direction as it goes downward in the vertical direction is provided at the upper end portion of the second portion 62c2 in the vertical direction.

  The positions in the depth direction of the two shield plate side engaging portions 64a of the side surface cover portion 64 and the shield plate side engaging portion 62c of the side end portion 62b1 are formed to be equal to each other (FIG. 7A). )reference).

  The connecting portion 63 is provided with a first cover connecting portion 63 a that is connected to the first cover portion 61, and a second cover connecting portion 63 b that is connected to the first cover connecting portion 63 a and connected to the second cover portion 62. ing. The first cover connecting portion 63a is formed to incline toward the back side in the depth direction as it goes downward in the vertical direction. The second cover connecting portion 63b is formed so as to extend along the depth direction.

  Next, a state in which the shield plate 60 is attached to the control circuit board 30 will be described with reference to FIGS. In FIG. 8, a member constituted by a broken line indicates an intermediate filter 75.

  As shown in FIG. 8A, the shield plate 60 covers the intermediate filter 75 from the surface side in the depth direction, both sides in the width direction, and the lower side in the vertical direction. The first cover portion 61 of the shield plate 60 is formed to be larger than the width in the width direction and the width in the vertical direction of the upper surface of the intermediate filter 75.

Specifically, the size relationship between the first cover portion 61 and the intermediate filter 75 is as follows.
In other words, the vertical distance D2 between the first cover portion 61 and the intermediate filter 75 is formed to be larger than one distance D1 between the first cover portion 61 and the intermediate filter 75 in the width direction. The distance D2 is formed to be larger than the distance D3 between the first cover portion 61 and the intermediate filter 75 in the vertical direction. Thereby, compared with the case where the distance D2 is equal to or less than the distances D1 and D3, noise (radiated noise) is less likely to enter from above in the vertical direction of the intermediate filter 75.

  Here, the distance D <b> 2 is determined by the vertical upper side surface (first side surface) not covered by the side surface cover portion 64 and the connecting portion 63 on the side surface of the intermediate filter 75 and the first cover portion 61 corresponding to this side surface. It is defined as the distance from the outer peripheral edge (that is, the upper end of the first cover portion 61 in the vertical direction). The distance D1 is the side surface (second side surface) covered with the side surface cover portion 64 on the side surface of the intermediate filter 75 and the outer peripheral edge of the first cover portion 61 corresponding to this side surface (that is, the width of the first cover portion 61). Defined as the distance to the end of the direction). Further, the distance D3 is the side surface (second side surface) covered by the connecting portion 63 on the side surface of the intermediate filter 75 and the outer peripheral edge of the first cover portion 61 corresponding to this side surface (that is, the vertical direction of the first cover portion 61). The distance to the lower end portion 9).

  The connecting portion 63 is disposed at a position corresponding to the outer peripheral edge of the filter mounting portion 32 c of the control circuit board 30. The difference in the vertical direction between the outer peripheral edge of the control circuit board 30 and the outer peripheral edge of the filter mounting portion 32 c is substantially the same as the plate thickness of the connecting portion 63. That is, one side 32b of the control circuit board 30 and the lower surface, which is the lower surface in the vertical direction of the connecting portion 63, are substantially flush. Thereby, it is suppressed that the connection part 63 protrudes largely downward from the outer periphery of the control circuit board 30 in the vertical direction.

  The shield plate side engaging portion 64a of each side cover portion 64 engages with the circuit board side engaging portion 32a of the control circuit board 30 so that the lower end portion in the vertical direction of each side cover portion 64 becomes the control circuit. The substrate 30 is positioned above the one side 32b below the vertical direction at the outer peripheral edge of the substrate 30 in the vertical direction.

  Since the side cover part 64 and the connecting part 63 are bent from the first cover part 61 downward in the depth direction, respectively, the first cover part 61 is compared with the structure in which the side cover part is bent from the connecting part. Intrusion of noise from between the cover part 61 and the side cover part 64 and the connecting part 63 is suppressed.

  As shown in FIG. 8B, the end portion 64 b of each side cover portion 64 is in contact with the surface of the printed wiring board 32. This suppresses noise from entering between the end 64b and the printed wiring board 32.

  As shown in FIG. 8C, the intermediate filter 75 and the side cover portions 64 are close to each other in the width direction. Thereby, in the surface of the printed wiring board 32, the area | region (namely, area | region between the width directions of each side surface cover part 64) which the electronic component which the shield board 60 occupies cannot be mounted small. Here, “proximity” refers to an interval at which an electronic component cannot be disposed between the intermediate filter 75 and each side cover portion 64.

  As shown to Fig.9 (a), the 2nd cover part 62 has covered the intermediate filter 75 from the back surface side of the depth direction by the opposing part 62a. The facing portion 62 a is formed to be larger in the vertical direction and the width direction than the lower surface of the intermediate filter 75. Further, the extension 62b covers the amplifier circuit 76 from the back side in the depth direction.

  The side end portion 62b1 is disposed above the one side 32b of the outer peripheral edge of the printed wiring board 32 in the vertical direction. Specifically, a portion below the side end portion 62b1 in the vertical direction is disposed in a cutout portion 32f provided in the printed wiring board 32. And the shield board side engaging part 62c is engaging with the protrusion part 32g which comprises both this notch part 32f and the insertion part 32e.

  As shown in FIG. 9B, the distance L1 in the depth direction between the back surface of the printed wiring board 32 and the second cover portion 62 is the printed wiring board 32 and the electronic component group mounted on the printed wiring board 32. Is substantially the same as the distance L2 in the depth direction with respect to the electronic component A having the largest physique. Specifically, the distance L1 is set to be slightly larger than the distance L2. With this configuration, the insulating plate 44 and the shield plate 60 come into contact before the insulating plate 44 and the electronic component A come into contact with each other.

  Next, an aspect in which the shield plate 60 is attached to the control circuit board 30 will be described with reference to FIGS. 10 and 11. 10A shows a state before the shield plate 60 is attached to the control circuit board 30, and FIG. 10B shows a state after the shield plate 60 is attached to the control circuit board 30. Yes. 11A shows a state before the shield plate side engaging portion 64a and the circuit board side engaging portion 32a are engaged, and FIG. 11B shows the shield plate side engaging portion 64a and the circuit. The state after the board | substrate side engaging part 32a engaged is shown.

  As shown in FIG. 10A, the shield plate 60 is inserted upward in the vertical direction with respect to the control circuit board 30 after each electronic component is mounted. At this time, each side surface cover portion 64 of the shield plate 60 is guided to the circuit board side engaging portion 32 a by the first inclined portion 32 d of the printed wiring board 32. Further, the side end portion 62b1 of the shield plate 60 is guided to the protruding portion 32g by the second inclined portion 32h of the printed wiring board 32.

  As shown in FIG. 10B, the printed wiring board 32, the side cover portions 64, and the side end portions 62b1 are joined by solder. One of the side cover portions 64 is electrically connected to the ground portion 32j of the wiring pattern provided on the printed wiring board 32 via solder.

  Referring to FIG. 11A, the shield plate side engaging portion 64a is inserted into the circuit board side engaging portion 32a from the lower side to the upper side in the vertical direction. At this time, each side cover part 64 is guided to the printed wiring board 32 by the first inclined part 64 c of each side cover part 64. And the 2nd site | part 62c2 of each shield board side engaging part 62c comes to be guided with respect to the printed wiring board 32 by the inclination part 62c3 of each shield board side engaging part 64a.

  Although not shown, the shield plate side engaging portion 62c is similarly guided with respect to the printed wiring board 32 by the second inclined portion 62b3 of the side end portion 62b1. And the 2nd site | part 62c2 of the shield board side engaging part 64a comes to be guided with respect to the printed wiring board 32 by the inclination part 62c3 of the shield board side engaging part 62c. As described above, the shield plate side engaging portions 64a and 62c are easily inserted into the circuit board side engaging portion 32a and the protruding portion 32g.

  Referring to FIG. 11B, the shield plate side engaging portion 64a and the circuit board side engaging portion 32a are in contact with each other in the depth direction. More specifically, the front surface and the back surface of the printed wiring board 32 are in contact with the end portion 64b of the side cover portion 64 constituting the shield plate side engaging portion 64a and the second portion 62c2. Thereby, the movement of the shield plate 60 (see FIG. 10) to both sides in the depth direction with respect to the control circuit board 30 (see FIG. 10) is restricted.

  Further, the circuit board side engaging portion 32a and the first portion 62c1 come into contact with each other in the vertical direction. That is, when the shield plate 60 is inserted into the control circuit board 30, it is inserted until the second portion 62c2 contacts the circuit board side engaging portion 32a.

According to the switch device 1 of the present embodiment, the following effects can be obtained.
(1) According to the present embodiment, the shield plate 60 is formed by bending a single metal plate while covering both sides of the intermediate filter 75 in the depth direction. According to this configuration, the shield plate 60 can suppress the influence of noise on the intermediate filter 75. Furthermore, since the shield plate 60 covers the intermediate filter 75 from both sides in the depth direction of the control circuit board 30, the number of surfaces that cover the intermediate filter 75 is increased, thereby further improving the effect of suppressing the influence of noise on the intermediate filter 75. Can be made.

  In addition, since the shield plate 60 is formed as a single member, for example, the number of parts of the switch device 1 as a whole can be reduced as compared with a case where the shield plate is composed of a plurality of members. Therefore, the cost of the switch device 1 can be reduced.

  Moreover, since the shield plate 60 is formed by bending, the cost for manufacturing the shield plate 60 can be reduced as compared with the case where the shield plate is formed by casting, for example. Therefore, the cost of the switch device 1 can be reduced.

  (2) According to the present embodiment, the connecting portion 63 is disposed below the outer peripheral edge (filter mounting portion 32 c) of the control circuit board 30 in the vertical direction. Therefore, a through hole for inserting the connecting portion 63 into the control circuit board 30 can be omitted. Therefore, in the control circuit board 30, it is possible to secure a space for mounting the electronic component group and a space for forming a wiring pattern for connecting the electronic component group. Alternatively, the size of the control circuit board 30 can be reduced.

  (3) According to the present embodiment, the shield plate 60 is provided with the side cover portion that covers the intermediate filter 75. Therefore, since the range of the shield plate 60 that covers the intermediate filter 75 is increased, the influence of noise on the intermediate filter 75 can be further suppressed.

  (4) According to the present embodiment, the filter mounting portion 32c is formed above the one side 32b of the outer peripheral edge of the control circuit board 30 in the vertical direction, and the recess formed by the outer peripheral edge and the filter mounting portion 32c. A connecting portion 63 is accommodated in 32b1. Therefore, compared with the configuration in which the connecting portion is disposed below the vertical edge of the outer peripheral edge of the control circuit board in the vertical direction, the size of the connecting part is increased in a state where the shield plate 60 is attached to the control circuit board 30. It becomes possible to suppress.

  (5) According to the present embodiment, when the shield plate 60 is inserted upward in the vertical direction with respect to the control circuit board 30, the shield plate side engaging portion 64a and the circuit board side engaging portion 32a are mutually connected. The shield plate side engaging portion 62c and the protruding portion 32g are engaged with each other. Therefore, the shield plate 60 and the control circuit board 30 can be easily assembled as compared with the case where the shield board is attached to the control circuit board from the depth direction.

  (6) According to this embodiment, the circuit board side engaging part 32a is provided in the outer periphery of the control circuit board 30 (printed wiring board 32). According to this configuration, compared with the case where the circuit board side engaging portion is provided in the central portion of the control circuit board, the mounting of the electronic component group and the formation of the wiring pattern are not hindered. The degree of freedom in setting the wiring pattern can be improved.

  In addition, since the side cover portion 64 can be arranged above the control circuit board in which the circuit board side engaging portion is omitted, the control circuit board 30 and the shield plate 60 are combined. An increase in size can be suppressed in the state.

  (7) According to the present embodiment, the intermediate filter 75 is mounted on the lower end of the printed wiring board 32 in the vertical direction and the other end in the width direction. Therefore, the shield plate 60 can be reduced in size as compared with the case where the intermediate filter is mounted on the central portion of the control circuit board. Accordingly, the metal plate forming the shield plate 60 can be made small, so that the material cost of the shield plate 60 can be reduced.

  (8) According to the present embodiment, the shield plate 60 is electrically connected to the ground portion 32j. Therefore, the shield plate 60 can further suppress the influence of noise received by the intermediate filter 75. In addition, it is possible to suppress the static electricity from affecting the intermediate filter 75 when the user pushes the switch device 1.

  (9) According to the present embodiment, the first cover portion 61 has a vertical distance D2 between the first cover portion 61 and the intermediate filter 75 such that the width direction between the first cover portion 61 and the intermediate filter 75 is the same. The distance D1 and the lower distance D3 in the vertical direction are larger. Accordingly, the distance in the vertical direction between the first cover part and the intermediate filter is formed to be the same or smaller than the distance in the width direction and the distance in the vertical direction between the first cover part and the intermediate filter. As compared with the above, the influence of noise received from the upper side surface of the intermediate filter 75 in the vertical direction can be suppressed.

  In particular, in the present embodiment, since the shield plate 60 is inserted upward from the lower side in the vertical direction of the intermediate filter 75, it is difficult to provide the side cover portion 64 on the upper side surface in the vertical direction of the intermediate filter 75. It is. That is, if the side cover 64 is provided in advance on the upper side surface of the intermediate filter 75 in the vertical direction, it becomes difficult to insert the shield plate 60 from the lower side of the intermediate filter 75 in the vertical direction. The ease of insertion with respect to the control circuit board 30 is reduced. In addition, a method is conceivable in which the shield plate 60 is inserted upward from below in the vertical direction of the intermediate filter 75 and then the upper side surface in the vertical direction of the intermediate filter 75 is covered by bending a part of the shield plate 60. However, in this method, since the shield plate 60 is bent after the shield plate 60 is attached to the control circuit board 30, it is difficult to manufacture the shield plate 60 by bending. Thus, a structure in which the side cover portion is simply omitted from the upper side surface of the intermediate filter 75 in the vertical direction is conceivable. However, with this structure, it is difficult to suppress the influence of noise on the upper side surface of the intermediate filter 75 in the vertical direction.

  In that respect, in this embodiment, since the range covering the upper part of the intermediate filter 75 of the first cover portion 61 in the vertical direction is increased, the ease of insertion of the shield plate 60 into the control circuit board 30 and the intermediate filter are increased. It is possible to achieve coexistence with the suppression of the influence of noise on the upper side surface of 75 in the vertical direction.

  (10) According to the present embodiment, the extension 62b of the shield plate 60 covers the amplifier circuit 76 from the back side in the depth direction. Therefore, the influence of noise received by the amplifier circuit 76 can be suppressed. As a result, the frequency band of the electrical signal adjusted by the intermediate filter 75 is further reduced from being affected by noise.

  (11) According to this embodiment, the intermediate filter 75 is mounted on the front surface of the printed wiring board 32, and the amplifier circuit 76 is mounted on the back surface of the printed wiring board 32. Therefore, the amplifier circuit 76 can be formed without depending on the shield plate 60. Therefore, the degree of freedom in forming the amplifier circuit 76 on the control circuit board 30 is improved.

  (12) According to the present embodiment, the distance L1 on the back surface side in the depth direction from the back surface of the printed wiring board 32 of the second cover portion 62 is greater than the distance L2 from the back surface of the printed wiring board 32 to the electronic component A. Slightly higher. Therefore, contact between the insulating plate 44 and the electronic component A can be avoided.

  (13) According to the present embodiment, the shield plate side engaging portion 64a and the circuit board side engaging portion 32a are both formed in a concave shape, and these are engaged with each other. According to this configuration, the movement of the shield plate 60 in the depth direction with respect to the control circuit board 30 is restricted. Therefore, it is possible to suppress the solder from being applied with the movement of the shield plate 60 relative to the control circuit board 30. As a result, since the electrical connection between the shield plate 60 and the ground portion 32j is ensured, the influence of static electricity on the shield plate 60 on the intermediate filter 75 can be suppressed. In addition, the shield plate 60 can be prevented from dropping off from the control circuit board 30.

  (14) According to the present embodiment, the side cover portions 64 are provided by being bent from both sides of the first cover portion 61 in the width direction. Therefore, since it is possible to prevent a gap from being formed at the connecting portion between the first cover portion 61 and the side surface cover portion 64, it is possible to prevent noise from entering through the gap.

  (15) According to the present embodiment, the side cover portion 64 and the surface of the printed wiring board 32 are in contact with each other. According to this configuration, since noise can be prevented from entering between the side cover portion 64 and the printed wiring board 32, the influence of noise received by the intermediate filter 75 can be suppressed.

  (16) According to the present embodiment, the intermediate filter 75 and the side cover portion 64 are close to each other in the width direction. According to this configuration, the area in which the electronic component cannot be mounted is reduced by the side cover portion 64, so that the degree of freedom in arranging the electronic component is improved.

  (17) According to the present embodiment, the printed wiring board 32 is provided with the first inclined portion 32d and the second inclined portion 32h. Therefore, the side cover portion 64 and the side end portion 62b1 of the shield plate 60 can be easily inserted into the control circuit board 30.

  In particular, since the end portion 64b of the side cover portion 64 abuts on the surface of the printed wiring board 32, the above effect is further improved as compared with the case where the side cover portion and the surface of the printed wiring board are separated from each other. Become.

  (18) According to the present embodiment, the shield plate side engaging portions 64a and 62c are provided with inclined portions 64a3 and 62c3, respectively. Therefore, the shield plate side engaging portion 64a can be easily inserted into the circuit board side engaging portion 32a, and the shield plate side engaging portion 62c can be easily inserted into the protruding portion 32g. It becomes like this.

  (19) According to the present embodiment, insertion is performed until the second portion 62c2 of the shield plate side engaging portion 64a and the circuit board side engaging portion 32a contact each other in the vertical direction. Thereby, since the insertion of the shield plate 60 can be confirmed with respect to the control circuit board 30 when the second portion 62c2 and the circuit board side engaging portion 32a contact each other, the control circuit board 30 The shield plate 60 can be easily attached.

  (20) According to this embodiment, the 1st cover connection part 63a of the connection part 63 is provided so that it may incline to the back surface side of a depth direction as it goes to the downward direction of a perpendicular direction. According to this configuration, when the operator inserts the shield plate 60 into the control circuit board 30, the finger can be placed on the first cover connecting portion 63a, so the first cover connecting portion is omitted from the shield plate. Compared with the case where it was made, the shield board 60 can be easily inserted upwards in the vertical direction.

(Other embodiments)
The switch device of the present embodiment is not limited to the above-described embodiment, and for example, the following changes can be made. Further, the following modifications are not only applied to the above-described embodiment, but can also be applied when different modifications are combined with each other.

  In the present embodiment, the intermediate filter 75 is mounted on the front surface of the printed wiring board 32 and the amplifier circuit 76 is mounted on the back surface of the printed wiring board 32, but the intermediate filter 75 is mounted on the back surface of the printed wiring board 32, The amplifier circuit 76 may be mounted on the surface of the printed wiring board 32. Further, the intermediate filter 75 and the amplifier circuit 76 can be mounted on the same surface of the printed wiring board 32.

In the present embodiment, the extension portion 62b is formed so that the shield plate 60 covers the amplifier circuit 76. However, the extension portion 62b can be omitted.
In the present embodiment, the circuit board side engaging portion 32a is provided on the printed wiring board 32, but the circuit board side engaging portion 32a may be omitted.

  In the present embodiment, the filter mounting portion 32c is provided above the one side 32b of the outer peripheral edge of the printed wiring board 32 in the vertical direction. However, the filter mounting portion 32c is perpendicular to the one side 32b of the printed wiring board 32. Can be provided at the same position or below.

  In the present embodiment, the side cover part 64 is provided by bending from the first cover part 61 of the shield plate 60, but the configuration of the side cover part 64 is not limited to this. For example, the side cover part 64 can also be formed so as to bend from both sides in the width direction of the connecting part 63 upward in the vertical direction.

  -In this embodiment, the 1st inclination which inclines in the width direction toward the downward direction of a perpendicular direction in the connection part of the circuit board side engaging part 32a in the printed wiring board 32, and the one side 32b of the outer periphery of the printed wiring board 32. Although the portion 32d is provided, the shape of the first inclined portion 32d is not limited to this. The first inclined portion 32d may be configured to guide each side cover portion 64 of the shield plate 60. Therefore, for example, the first inclined portion 32d can also have a curved surface shape.

  Similarly, a connecting portion between one side edge in the width direction of the printed wiring board 32 constituting the cutout portion 32f of the printed wiring board 32 and one side 32b in the outer circumferential edge of the printed wiring board 32 is below the vertical direction. Although the second inclined portion 32h that is inclined in the opposite width direction is provided, the second inclined portion 32h can also have a curved surface shape.

  In the present embodiment, the upper end in the vertical direction and the end on the back side in the depth direction of each side surface cover portion 64 of the shield plate 60 are inclined toward the front side in the depth direction as going upward in the vertical direction. Although the first inclined portion 64c is provided, the shape of the first inclined portion 64c is not limited to this. Since the 1st inclination part 64c should just be a structure which can be smoothly inserted in the printed wiring board 32, the 1st inclination part 64c can also be made into a curved-surface shape, for example.

  Similarly, the second upper end of the side end 62b1 of the shield plate 60 and the end on the front side in the depth direction are inclined toward the back side in the depth direction as going upward in the vertical direction. Although the inclined portion 62b3 is provided, the second inclined portion 62b3 can also have a curved shape.

  -In this embodiment, although the connection part 63 was provided in the exterior (downward of the perpendicular direction) rather than the filter mounting part 32c, this invention is not limited to this. For example, as shown in FIG. 12, in the printed wiring board 32, a through hole 32k that penetrates the printed wiring board 32 in the depth direction can be formed, and a connecting portion 63 can be inserted into the through hole 32k. In this case, the second cover portion 62 can be formed by bending the shield plate 60 as indicated by the arrow in FIG. 12 after the connecting portion 63 is inserted into the through hole 32k.

  In this embodiment, the intermediate filter 75 is mounted on the lower end of the printed wiring board 32 in the vertical direction and on the other end in the width direction, but the intermediate filter 75 is mounted on the center of the printed wiring board 32. You can also

  -In this embodiment, although the shield board 60 was attached to the control circuit board 30, since the shield board 60 should just be the aspect which covers the intermediate filter 75, it is not limited to this attachment aspect. For example, the shield plate 60 can be attached to the intermediate cover 12.

  In the present embodiment, the control is performed by inserting the shield plate 60 in which the first cover portion 61, the second cover portion 62, and the connecting portion 63 are formed by bending a metal plate in advance into the control circuit board 30 from the vertical direction. Although the shield plate 60 is attached to the circuit board 30, the manner of attachment of the shield board 60 and the control circuit board 30 is not limited to this. For example, the second cover part 62 can be formed by bending after the shield plate 60 on which the first cover part 61 and the connecting part 63 are formed is attached to the control circuit board 30.

  -In this embodiment, although the shield plate 60 was the structure which covers the intermediate filter 75, the object which the shield plate 60 shields is not limited to this. The shield plate 60 can also be configured to cover other filters.

  In the present embodiment, the switch device 1 controls turning off and lighting of the lighting load L by turning the switch device 1 on and off, but the control mode of the switch device 1 is limited to this. There is nothing. For example, the switch device 1 can also adjust the dimming of the illumination load L. Moreover, the switch apparatus 1 is not limited to the illumination load L, It can also control other loads, such as a ventilation fan.

  DESCRIPTION OF SYMBOLS 1 ... Switch apparatus, 1A ... Switch main-body part, 1B ... Terminal part, 1C ... Circuit part, 1D ... Operation part, 2A-2C ... Fire alarm device, 3 ... Operation terminal device, 4 ... Interphone main machine, 5 ... Interphone child 10, mounting frame, 10 b, first fixing portion, 10 c, second fixing portion, 11, body, 11 a, peripheral wall portion, 11 b, bottom wall portion, 11 c, terminal storage portion, 11 d, electronic component storage portion, 12 ... Intermediate cover, 12a ... Operation button, 12b ... Mounting frame fixing part, 12c ... Body fixing part, 20 ... Release button, 21 ... Lock spring, 22 ... Terminal board, 30 ... Control circuit board (circuit board), 31 ... Load Control part 32 ... Printed wiring board 32a ... Circuit board side engaging part, 32b ... One side, 32b1 ... Recessed part, 32c ... Filter mounting part, 32d ... First inclined part, 32e ... Insertion part, 32f ... Notch part, 32g ... projection, 32h ... second slope 32j ... Ground part, 33 ... Connector, 34 ... Push button switch, 40 ... Power supply circuit board, 41 ... Printed wiring board, 42 ... Transistor, 43 ... Heat sink, 44 ... Insulating plate, 50 ... Operating handle, 50a ... Locking Claw, 51 ... leaf spring, 60 ... shield plate, 61 ... first cover part, 62 ... second cover part, 62a ... opposing part, 62b ... extension part, 62b1 ... side end part, 62b2 ... end part, 62c ... shield Plate side engaging part, 62c1 ... 1st part, 62c2 ... 2nd part, 62c3 ... Inclination part, 63 ... Connection part, 63a ... 1st cover connection part, 63b ... 2nd cover connection part, 64 ... Side cover part, 64a ... shield plate side engaging part, 64a1 ... first part, 64a2 ... second part, 64a3 ... inclined part, 64b ... end part, 64c ... first inclined part, 70 ... antenna (receiving part), 71 ... RF filter , 72 Vibrator, 73 ... local filter, 74 ... mixer, 75 ... intermediate filter (filter), 76 ... amplifier, 77 ... demodulating portion, 78 ... microcomputer.

Claims (10)

A receiver that receives radio waves from the outside and converts the radio waves into electrical signals; a filter that adjusts a frequency band of the electrical signals received by the receiver; and a circuit board on which the filters are mounted. In a switching device in which a load is controlled based on a signal,
The switch device is provided with a shield plate that covers the filter from both sides in the thickness direction of the circuit board,
The said shield board is comprised from a single member. The switch apparatus characterized by the above-mentioned. The switch device according to claim 1,
The shield plate includes a first cover portion that covers the filter from one side in the plate thickness direction, a second cover portion that covers the filter from the other side in the plate thickness direction via the circuit board, and the first cover portion. A connecting portion that connects the cover portion and the second cover portion in the plate thickness direction;
The switch device is characterized in that the connecting portion is arranged outside the outer peripheral edge of the circuit board. The switch device according to claim 2,
The switch device, wherein the first cover portion is provided with a side cover portion that covers a side surface of the filter. In the switch apparatus as described in any one of Claims 1-3,
The circuit board is provided with a circuit board side engaging portion that is recessed in one direction perpendicular to the plate thickness direction,
The shield plate is provided with a shield plate side engaging portion that is recessed in a direction opposite to the one direction,
The switch device is characterized in that the circuit board side engaging portion and the shield plate side engaging portion are engaged with each other when the shield plate is inserted in the one direction with respect to the circuit board. The switch device according to claim 4,
The circuit board-side engagement portion is provided on an outer peripheral edge of the circuit board. The switch device according to claim 4 or 5,
The switch device, wherein the filter is mounted in proximity to the circuit board side engaging portion. The switch device according to claim 3,
The distance between the first side surface that is not covered by the side surface cover portion and the connecting portion on the side surface of the filter and the outer peripheral edge of the first cover portion corresponding to the first side surface is determined by the side cover portion and the connecting portion. The switch device is characterized in that it is formed to be larger than the distance between the second side surface covered with the outer peripheral edge of the first cover portion corresponding to the second side surface. In the switch apparatus as described in any one of Claims 1-7,
The switch device, wherein the shield plate is electrically connected to a ground portion serving as a reference potential of the circuit board. In the switch apparatus as described in any one of Claims 1-8,
The circuit board is provided with an amplifier circuit that amplifies the frequency band of the electrical signal adjusted by the filter,
The switch device, wherein the shield plate covers the amplifier circuit. The switch device according to claim 9, wherein
The switch device, wherein the amplifier circuit is formed on a surface opposite to a surface of the circuit board on which the filter is mounted.

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