JP5277127B2 - Instrument device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an instrument device that achieves both dustproofing on a display device and heat dissipation on heat-producing components. <P>SOLUTION: The interior of an instrument case 5 of the instrument device 1A is divided into a hermetically sealed dustproof chamber 51 and a heat dissipation chamber 52 having a vent 16 on its outer wall. A partition wall 22 partitioning the dustproof chamber 51 and the heat dissipation chamber 52 has a wiring hole 22a. A liquid crystal display 6, an analog meter 7, and a relay board 8 on which the liquid crystal display 6 and the analog meter 7 are electrically connected with each other are hermetically encapsulated in the dustproof chamber 51. A printed circuit board 9 and a graphic board 10 are housed within the heat dissipation chamber 52. Connectors 11, 12, which are connected with each other through the wiring hole 22a, are mounted on the relay board 8 and the printed circuit board 9, respectively. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to an instrument device mounted on a moving body such as a vehicle or a ship.

  A moving body such as a vehicle or a ship is equipped with an instrument device that displays a plurality of information measured by various measuring units to a driver of the moving body. FIG. 7 is a cross-sectional view showing a conventional instrument device.

  An instrument device 200 shown in FIG. 7 includes a liquid crystal display 204 that displays a scale such as a speedometer, a pointer 205 that displays a measurement amount in cooperation with the scale displayed on the liquid crystal display 204, and rotates the pointer 205. A movement 207 to be moved, a liquid crystal display 204, a printed circuit board 206 for controlling the movement 207, an instrument case 201 for accommodating these, and the like.

  The instrument case 201 is formed in a box shape, and includes a case main body 203 provided with an opening 203a on the driver side, and a transparent front cover 202 covering the opening 203a. The instrument case 201 is sealed so that dust or the like does not enter the instrument device 200.

JP 2006-17490 A

  However, the above-described instrument device 200 has the following problems. That is, the instrument device 200 needs to dissipate the heat of the printed circuit board 206 having a large calorific value, but the instrument case 201 in which the printed circuit board 206 is housed is hermetically sealed to prevent entry of dust and the like. The instrument device 200 using such an instrument case 201 has a problem that the heat dissipation of the printed circuit board 206 is low. In addition, the above-described heat dissipation problem is a problem that can occur in the heat generating parts other than the printed circuit board 206 as well.

  Therefore, the present invention focuses on the above-described problems, and an object of the present invention is to provide an instrument device that can perform both dustproofing of a display and heat dissipation of a heat-generating component.

In order to achieve the above object, the invention described in claim 1 is an instrument device in which an indicator for displaying predetermined information is accommodated in an instrument case, wherein the inside of the instrument case is sealed against dust. And a heat radiating chamber in which a heat generating component is accommodated and a vent hole is provided in the outer wall, and a printed circuit board as the heat generating component is accommodated in the heat radiating chamber and electrically connected to the display. A relay board is hermetically sealed in the dustproof chamber, a wiring hole is provided in a partition wall separating the dustproof chamber and the heat dissipation chamber, and the relay board and the printed board are connected to each other through the wiring hole. The instrument device is characterized in that each connector is mounted .

The invention described in claim 2 is characterized in that in the invention described in claim 1 , it has at least one of a liquid crystal display as the display and an analog meter as the display. To do.

According to the first aspect of the present invention, the inside of the instrument case is divided into a dustproof chamber in which the indicator is sealed, and a heat radiating chamber in which a heat generating component is accommodated and a vent hole is provided in the outer wall. Therefore, it is possible to provide an instrument device that can perform both dustproofing of the display and heat dissipation of the heat-generating component.
In addition, a printed circuit board as the heat generating component is accommodated in the heat dissipation chamber, a relay substrate electrically connected to the display is sealed in the dustproof chamber, and a wiring hole is formed in a partition wall separating the dustproof chamber and the heat dissipation chamber. Since the connectors that are connected to each other through the wiring holes are mounted on the relay board and the printed board, respectively, the electrical connection between the dust-proof chamber side component and the heat-radiation chamber side component is performed. It is possible to provide an instrument device that can be performed only by the connection work between a pair of connectors and can be easily assembled. In addition, only one wiring hole can be provided in the partition wall, and the dustproof property of the dustproof chamber can be improved.

According to the second aspect of the present invention, since at least one of the liquid crystal display as the display and the analog meter as the display is included, dust prevention and heat generation of the liquid crystal display or analog meter It is possible to provide an instrument device that can perform both heat dissipation of components.

It is a perspective view which shows the instrument apparatus which concerns on one Embodiment of this invention. It is a perspective view which shows the case main body which comprises the instrument case of the instrument apparatus shown by FIG. It is the schematic of the cross section along the AA line in FIG. It is sectional drawing along the BB line in FIG. It is a perspective view which shows the meter apparatus of a reference example . It is the schematic of the cross section along CC line in FIG. It is sectional drawing which shows the conventional instrument apparatus.

( One embodiment of the present invention )
An instrument device according to an embodiment of the present invention will be described with reference to FIGS. An instrument device 1A shown in FIG. 1 is mounted on a moving body such as a vehicle, and with respect to the driver of the moving body, the speed of the moving body, the engine speed, the remaining amount of fuel, the temperature of the engine cooling water, It is a device that displays predetermined information such as.

  As shown in FIGS. 1 and 3, the instrument device 1A includes a liquid crystal display 6 as a display for displaying the predetermined information, an analog meter 7 as a display for displaying the predetermined information, and the liquid crystal display 6 As a heat generating component that controls the liquid crystal display 6 and the analog meter 7 by being electrically connected to the analog meter 7 via the electric wires 17 and the like, and the relay substrate 8 being electrically connected to the relay substrate 8 via the connectors 11 and 12. A printed circuit board 9, a graphic board 10 as a heat generating component that is electrically connected to the printed circuit board 9 through the connectors 13 and 14 and outputs an electrical signal for displaying the predetermined information on the liquid crystal display 6, and these And an instrument case 5 in which is housed.

  The instrument case 5 is made of a synthetic resin and has a case main body 2 to which various components are attached, a front cover 3 attached to the front surface of the case main body 2, and a back cover formed of metal and attached to the back surface of the case main body 2. 4. Moreover, the arrow X shown in FIGS. 1 to 3 indicates the width direction of the instrument case 5, the arrow Y indicates the height direction of the instrument case 5, and the arrow Z indicates the depth direction of the instrument case 5.

  As shown in FIGS. 2 and 3, the case main body 2 includes a frame portion 20 that extends in a cylindrical shape in the arrow Z direction, and the inner space of the frame portion 20 on the front side along the arrow Z direction, that is, on the driver side. , And a partition wall 22 partitioned into two spaces, that is, one space located on the rear side and the other space located on the back side along the arrow Z direction. Further, the one space located on the front side along the arrow Z direction, that is, on the driver side, constitutes a dustproof chamber 51 described later. Further, the other space located on the back side along the arrow Z direction constitutes a heat radiating chamber 52 described later. Further, reference numeral 2a in FIG. 3 indicates one opening located on the front side along the arrow Z direction of the frame part 20, that is, the driver side, and reference numeral 2b indicates in the arrow Z direction of the frame part 20. The other opening part located in the back side along is shown. In addition, a plurality of inner walls for attaching various components are provided inside the frame portion 20. In FIG. 3, the inner wall is omitted.

  Further, as shown in FIGS. 2 and 3, the partition wall 22 has a wiring hole 22 a that communicates the one space with the other space, that is, communicates the dustproof chamber 51 and the heat radiating chamber 52. Is provided. The wiring hole 22a is for passing the connector 11 mounted on the relay substrate 8 sealed in one space, that is, the dustproof chamber 51, to the other space, that is, the heat radiating chamber 52 side. In addition, as shown in FIG. 2, the partition wall 22 is provided with a plurality of screw attachment portions 23 for screwing the screws for attaching the back cover 4 to the case body 2.

  The front cover 3 is attached to the front side of the case body 2 along the arrow Z direction and covers one opening 2a of the frame portion 20. The front cover 3 is formed of a synthetic resin in a frame shape and is overlapped with the frame portion 20, and a facing plate 32 is formed in a plate shape and attached to the inside of the second frame portion 30. It has a transparent plate portion 31 which is formed in a plate shape with a transparent synthetic resin and is arranged on the driver side, that is, the front side of the facing plate 32. The facing plate 32 is provided with an exposure window 32a that exposes a dial 73 of the analog meter 7 described later to the driver, and an exposure window 32b that exposes the liquid crystal display 6 to the driver. Yes. The front cover 3 is attached to the case body 2 so as to cover the opening 2a and constitute a “dust-proof chamber 51” which is a sealed space.

  The dust-proof chamber 51 is hermetically sealed with the frame portion 20, the partition wall 22, the second frame portion 30, and the transparent plate portion 31, thereby preventing entry of dust and the like. In the dustproof chamber 51, the liquid crystal display 6, the analog meter 7, and the relay substrate 8 are sealed. Further, the connector 11 as a wiring member mounted on the relay substrate 8 passes through the wiring hole 22a and protrudes toward the other space, that is, the heat radiation chamber 52 side.

  The said back cover 4 is attached to the back side along the arrow Z direction of the case main body 2, and covers the other opening part 2b of the frame part 20. As shown in FIG. The back cover 4 is provided with a plurality of ventilation holes 16. The back cover 4 is attached to the case body 2 so as to cover the opening 2 b and constitute a “heat radiation chamber 52” which is a space communicating with the outside of the instrument case 5. The metal back cover 4 electromagnetically shields the printed circuit board 9 and the like. Moreover, in this embodiment, the back cover 4 is formed of SECC (electrogalvanized steel sheet).

  The heat radiating chamber 52 accommodates the printed circuit board 9 and the graphic board 10 that generate a large amount of heat. The heat radiating chamber 52 cools the air heated by the printed circuit board 9 and the graphic board 10 by the metal back cover 4 and discharges the air from the vent hole 16 to the outside of the instrument case 5. Dissipate heat.

  The printed circuit board 9 is mounted with a connector 12 as a wiring member that is electrically connected to the connector 11 of the relay board 8 that protrudes toward the heat radiation chamber 52 through the wiring hole 22a. Further, the printed circuit board 9 and the graphic board 10 are equipped with connectors 13 and 14 that are electrically connected to each other. The above-described connectors 11, 12, 13, and 14 are well-known “B to B connectors”, that is, “board-to-board connectors”.

  Further, as shown in FIG. 4, since the CPU 15 mounted on the graphic board 10 is a particularly high-temperature component, the CPU 15 is provided with the following heat dissipation structure. That is, on the surface of the CPU 15, a heat conductive sheet 19 that attaches to the back cover 4 and dissipates heat generated by the CPU 15 to the back cover 4 is attached. Further, the portion 18 of the back cover 4 that comes into contact with the heat conductive sheet 19 is punched into a convex shape, thereby increasing the surface area and improving the heat dissipation.

  The analog meter 7 constitutes a fuel meter in the present embodiment. As shown in FIG. 3, the analog meter 7 includes a printed board 74 electrically connected to the relay board 8, a movement 70 electrically connected to the printed board 74, and a dial 73 on which a scale of the fuel meter is printed. And a pointer 72 that is attached to the rotating shaft 71 of the movement 70 and displays the measured amount, that is, the remaining amount of fuel in cooperation with the scale of the dial 73. In addition, the movement 70 is connected to a measurement unit (not shown) mounted on the moving body via the relay board 8 and the like, and the rotation shaft 71 corresponds to the measurement amount measured by the measurement unit, that is, the remaining amount of fuel. Rotate.

  Such an instrument device 1A of the present invention is provided with a partition wall 22 at the center of the instrument case 5 and two spaces in the instrument case 5, that is, a dustproof chamber 51 and a heat radiating chamber 52. In addition, both dustproofing of the analog meter 7 and heat dissipation of the printed circuit board 9 and the graphic board 10 can be performed. Moreover, in this invention, it can be set as the instrument apparatus 1A which can perform dust prevention and heat dissipation which were mentioned above by simple structure by providing the wiring hole 22a in the partition wall 22. FIG.

  Further, in the present invention, the electric wires 17 connected to the parts on the dustproof chamber 51 side, that is, the liquid crystal display 6 and the analog meter 7 are gathered on the relay board 8 and the connector 11 mounted on the intermediate board 8 is printed. By connecting to the connector 12 mounted on the substrate 9, the dust-proof chamber 51 -side component and the heat-dissipating chamber 52 -side component are electrically connected, so that the dust-proof chamber 51 -side component and the heat-dissipating chamber 52 -side component are connected. Can be made only by the connection work between the pair of connectors 11 and 12, and the instrument device 1A can be easily assembled. Further, by using the pair of connectors 11 and 12, only one wiring hole 22 a can be provided in the partition wall 22, and the dustproof property of the dustproof chamber 51 can be improved. Further, the wiring hole 22a of the present invention has a minimum size that allows the connector 11 to pass therethrough.

  In the present embodiment, the connector 11 on the relay board 8 side passes through the wiring hole 22a and protrudes toward the heat radiating chamber 52, and is connected to the connector 12 on the printed board 9 side. A configuration in which the connector 12 on the substrate 9 side passes through the wiring hole 22a and protrudes toward the dust-proof chamber 51 may be employed.

  In the present embodiment, the back cover 4 is made of metal. However, in the present invention, the back cover 4 may be made of synthetic resin or the like. Further, by forming the back cover 4 from metal, the back cover 4 can have an electromagnetic shielding function and a heat sink function in addition to the component protection function and the ventilation function.

( Reference example )
Subsequently, a reference instrument device which is not a present invention but serves as a reference will be described with reference to FIGS. 5 and 6. 5 and 6, the same components as those in the first embodiment described above are denoted by the same reference numerals and description thereof is omitted.

Total instrument system 1B shown in FIGS. 5 and 6, the liquid crystal display 6, an analog meter 7, the printed circuit board 9 that is electrically connected through these liquid crystal display 6 and analog meter 7 and the wire 17, the printed circuit board 9 And a graphic board 10 electrically connected via connectors 13 and 14 and an instrument case 105 containing these.

  The instrument case 105 is formed of a first case 102 made of synthetic resin, the front cover 3 attached to the front surface of the first case 102, and made of metal, and attached to the back surface of the first case 102. The second case 104 is formed.

  The first case 102 includes a frame portion 120 that extends in a cylindrical shape in the arrow Z direction, and a back wall 122 that closes the other opening portion 102b located on the back side of the frame portion 120 along the arrow Z direction. , And is formed in a box shape.

  The front cover 3 is attached to the first case 102 so as to cover the one opening 102a located on the front side along the arrow Z direction of the frame 120, and is a sealed space "dustproof chamber 151" Configure. In this dustproof chamber 151, the liquid crystal display 6 and the analog meter 7 are sealed.

  The second case 104 has a box shape in which a front case 140 and a back cover 141 are assembled to each other. The front case 140 has a plate-like overlapping wall 140a that is stacked on the back wall 122 of the first case 102, and standing walls 140b and 140c that are erected from the outer edge of the overlapping wall 140a. Moreover, the code | symbol 124 in FIG. 6 has shown the boss | hub which positions the back wall 122 and the overlap wall 140a. The back cover 141 includes a plate portion 141a facing the overlapping wall 140a, and standing walls 141b and 141c that are erected from the outer edge of the plate portion 141a and overlap the standing walls 140b and 140c of the front case 140. doing. The back cover 141 is provided with a plurality of vent holes 16. Such an internal space of the second case 104 communicating with the outside is referred to as a “heat radiation chamber 152” in the present invention. The heat dissipation chamber 152 accommodates the printed circuit board 9 and the graphic board 10.

Furthermore, in the instrument device 1B , in order to improve the heat dissipation performance of the heat radiating chamber 152, a standing wall 141b located at the lowermost part of the heat radiating chamber 152 in the arrow Y direction (arrow Y is parallel to the gravity direction); A plurality of vent holes 16 are provided in the standing wall 141c located at the top. By providing the vent hole 16 in such a position, in the heat radiating chamber 152, the air heated by the printed circuit board 9 and the graphic board 10 moves to the upper part in the arrow Y direction and from the vent hole 16 of the standing wall 141c. A low temperature outside air is discharged outside (indicated by an arrow H in FIG. 6), and convection (indicated by an arrow G in FIG. 6) flows into the heat radiation chamber 152 from the vent hole 16 of the standing wall 141b. Efficient heat dissipation is performed by this convection.

In addition, wiring holes 122a and 142 that overlap each other are provided in the back wall 122 that constitutes the dust-proof chamber 151 and the overlapping wall 140a that constitutes the heat dissipation chamber 152, respectively. The electric wire 17 as a wiring member electrically connected to the liquid crystal display 6 and the analog meter 7 sealed in the dustproof chamber 151 passes through the wiring holes 122a and 142 and is accommodated in the heat radiating chamber 152. It is electrically connected to.

In the embodiment and the reference example of the present invention described above, the dustproof chambers 51 and 151 and the heat radiating chambers 52 and 152 are arranged along the depth direction of the instrument cases 5 and 105, that is, the arrow Z direction. However, in the instrument device of the present invention, the dustproof chamber and the heat radiating chamber may be arranged along the width direction of the instrument case, or arranged along the height direction of the instrument case. Also good.

  In addition, embodiment mentioned above only showed the typical form of this invention, and this invention is not limited to embodiment. Various modifications can be made without departing from the scope of the present invention.

1A, 1B Instrument device 5,105 Instrument case 6 Liquid crystal display (display)
7 Analog meter (display)
9 Printed circuit boards (heat generating parts)
10 Graphic board (heat generation component)
16 Vent 51,151 Dust-proof chamber 52,152 Radiation chamber

Claims (2)

In an instrument device in which an indicator for displaying predetermined information is accommodated in an instrument case,
The inside of the instrument case is divided into a dust-proof chamber in which the indicator is sealed, and a heat-dissipating chamber in which heat-generating components are housed and vents are provided on the outer wall ,
A printed circuit board as the heat generating component is accommodated in the heat dissipation chamber,
A relay board electrically connected to the display is sealed in the dustproof chamber,
A wiring hole is provided in a partition wall separating the dust-proof chamber and the heat-dissipating chamber,
A connector that is mounted on the relay board and the printed board and that is connected to each other through the wiring hole . The instrument device according to claim 1 , comprising at least one of a liquid crystal display as the display and an analog meter as the display.

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