JP2017208452A - Electronic device and filter device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic device and a filter device, which can suppress increase of a temperature of a heating member.SOLUTION: An electronic device 100 comprises: a circuit substrate 10; a casing body 20; and a filter device 40. The filter device 40 is provided to the casing body 20, suppresses an entry of a liquid in an outer part space 200 to a housing space 22, and can vent between the housing space 22 and the outer part space 200. The filter device 40 includes a filter case 44 and a filter 42. In the filter case 44, an inner side hole 60a and an inner side passage 60d and an outer side hole 60b and an outer side passage 60c are formed as a ventilation passage. The inner side hole 60a and the inner side passage 60d are not crossed to the outer side hole 60b and the outer side passage 60c. The minimal length to the circuit substrate 10 of an opening of the circuit substrate 10 side in the inner side hole 60a is formed shorter than that of the opening of the circuit substrate 10 side in the outer side hole 60b.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an electronic device including an electronic component, a housing, and a filter device, and a filter device.

  Conventionally, as described in Patent Document 1, a ventilation member fixed to an opening of a housing is known. The ventilation member has a support body fixed to the housing and a ventilation film fixed to the support body. The support is formed with a through hole for allowing the accommodating space to communicate with the external space. In the support body, a plurality of through-holes opened to the gas permeable membrane side are formed to be one on the accommodation space side. The gas permeable membrane is fixed to the support so as to cover the through hole.

JP 2009-29423 A

  By the way, the structure by which a heat generating member is arrange | positioned in accommodation space can be considered. Due to the heat generated by the heat generating member, the temperature of the accommodation space becomes higher than the temperature of the external space. According to this, the atmospheric pressure in the accommodation space becomes higher than the atmospheric pressure in the external space. Therefore, high-temperature air flows from the accommodation space through the ventilation member to the external space. At this time, the high-temperature air flows to the external space through the through hole and the gas permeable membrane.

  In the above configuration, since all the through holes are one on the accommodation space side, the shortest distance between the opening on the heat generating member side and the heat generating member in the through hole is the same for all the through holes. Therefore, when the temperature of the accommodation space rises, air flows from the accommodation space side to the external space side through all the through holes. Therefore, it is difficult for the air in the external space, which has a lower temperature than the housing space, to flow into the housing space through the through hole. Therefore, the air in the housing space is not easily cooled by the air in the external space. According to this, there exists a possibility that the temperature of an accommodation space may become high and the temperature of a heat generating member may become high.

  This invention is made | formed in view of such a subject, and it aims at providing the electronic device and filter apparatus which can suppress that the temperature of a heat generating member becomes high.

  The present invention employs the following technical means to achieve the above object. In addition, the code | symbol in parenthesis shows the correspondence with the specific means in the following embodiment as one aspect | mode, and does not limit a technical range.

One aspect of the present invention is
A heating member (10);
A housing (20) in which the heat generating member is housed in the housing space (22), and the housing space is watertightly sealed,
A filter device (40) that is provided in the housing and prevents the liquid in the external space (200) from entering the storage space and allows ventilation between the storage space and the external space;
With
The filter device is provided with a filter case (44) in which a plurality of ventilation paths for allowing the accommodation space to vent with the external space are formed, and has waterproofness and air permeability. A filter (42),
In the filter case, a first path (60a, 60d) and a second path (60b, 60c) formed so as not to intersect the first path are formed as ventilation paths,
The opening on the heat generating member side in the first path is shorter than the opening on the heat generating member side in the second path.

  In the above configuration, the opening on the heat generating member side in the first path is shorter than the opening on the heat generating member side in the second path. According to this, when the temperature of the heat generating member rises, the air around the heat generating member in the accommodation space passes through the first path more easily than the second path when flowing to the external space. That is, air having a relatively high temperature is easier to pass through the first path than the second path.

  When air flows from the storage space to the external space, the atmospheric pressure around the heat generating member in the storage space decreases. However, in the first path, since air flows from the accommodation space side to the external space side, it is difficult for air to flow from the external space to the accommodation space even when the pressure in the accommodation space decreases. On the other hand, in the second path, it is difficult for air to flow from the accommodation space side to the external space side as compared to the first path. For this reason, when the air pressure in the accommodation space decreases, air easily flows from the external space side to the accommodation space side in the second path. That is, air having a relatively low temperature in the external space flows through the second path to the periphery of the heat generating member having a low atmospheric pressure in the accommodation space.

  According to the above, high temperature air can be flowed from the periphery of the heat generating member to the external space, and low temperature air can be flowed from the external space to the periphery of the heat generating member. Therefore, it can suppress that a heat generating member becomes high temperature.

One of the other inventions is
Provided in the housing (20) for housing the heat generating member (10) in the watertight sealed housing space (22), the liquid in the external space (200) is prevented from entering the housing space, and the housing space and the outside A filter device that enables ventilation with a space,
A filter case (44) having a plurality of ventilation paths for allowing the accommodation space to ventilate with the external space;
A filter (42) that is waterproof and breathable, is disposed in the filter case and closes all ventilation paths;
In the filter case, a first path (60a, 60d) and a second path (60b, 60c) formed so as not to intersect the first path are formed as ventilation paths,
The opening on the heat generating member side in the first path is shorter than the opening on the heat generating member side in the second path.

  With the above configuration, it is possible to achieve the same effect as the electronic device described above.

It is sectional drawing which shows schematic structure of the electronic device which concerns on 1st Embodiment. It is a perspective view which shows schematic structure of a filter apparatus. It is sectional drawing which follows the III-III line of FIG. It is a side view which shows schematic structure of a filter apparatus. It is a top view which shows the structure of a filter. It is a top view which shows schematic structure of a main-body part. It is sectional drawing which shows schematic structure of a filter apparatus in the electronic device which concerns on 2nd Embodiment. It is a perspective view which shows schematic structure of a main-body part.

  This will be described with reference to the drawings. In a plurality of embodiments, common or related elements are given the same reference numerals. Further, the thickness direction of the filter is indicated as the Z direction, the specific direction orthogonal to the Z direction is indicated as the X direction, and the direction orthogonal to the Z direction and the X direction is indicated as the Y direction. A plane defined by the X direction and the Y direction is referred to as an XY plane. A shape along the XY plane is referred to as a planar shape.

(First embodiment)
First, a schematic configuration of the electronic device 100 will be described with reference to FIGS.

  As shown in FIG. 1, the electronic device 100 includes a circuit board 10, a housing 20, and a filter device 40. In the present embodiment, the electronic device 100 is disposed in a vehicle. Specifically, the electronic device 100 is disposed in an engine compartment of a vehicle or a vehicle interior. The electronic device 100 is an ECU for a vehicle. The electronic device 100 can also be referred to as an electronic control device.

  The circuit board 10 includes a board 12, a connector 13 for electrical connection with the outside of the electronic device 100, and an electronic component 14 mounted on the board 12. The substrate 12 has a substantially flat plate shape whose thickness direction is along the Z direction. The substrate 12 has one surface 12a and a back surface 12b. The connector 13 electrically relays the external device and the circuit board 10. The electronic component 14 is arrange | positioned on both surfaces of the one surface 12a and the back surface 12b. However, an example in which the electronic component 14 is disposed only on one side of the substrate 12 can also be adopted. The circuit board 10 has, as the electronic component 14, a heat generating component that generates a relatively large amount of heat as compared with other electronic components 14. For example, a MOS or a diode can be used as the heat generating component. The temperature of the heat generating component rises to about 120 ° C. by driving, for example.

  The housing 20 houses the circuit board 10 in the housing space 22. The housing 20 is formed using, for example, a resin material or a metal material. The housing 20 has a first case 24 and a second case 26. The first case 24 and the second case 26 have a box shape with one surface open. The first case 24 and the second case 26 are arranged so as to close each other's opening. Hereinafter, the opening of the first case 24 closed by the second case 26 is referred to as an opening 24a.

  The first case 24 has a bottom portion 28 and a side wall portion 30. The bottom portion 28 has a substantially flat plate shape whose thickness direction is along the Z direction. The bottom portion 28 has a front surface 28a that defines the accommodation space 22, and a back surface 28b opposite to the front surface 28a. The front surface 28a and the back surface 28b are planes orthogonal to the Z direction. The side wall portion 30 extends in the Z direction from the outer peripheral portion of the bottom portion 28 on the XY plane. An end portion of the side wall portion 30 opposite to the bottom portion 28 forms an opening 24a.

  An opening 30 a for the connector 13 is formed in one side wall 30. The opening 30 a is formed so that the connector 13 is exposed to the external space 200. A part of the connector 13 is exposed to the external space 200 from the part connected to the substrate 12 through the opening 30a. In the present embodiment, the opening 30a communicates with the opening 24a. That is, the opening 30a is open to the second case 26 side in the Z direction at a location not shown.

  The first case 24 and the second case 26 are fixed to each other by screw fastening or the like. A seal material (not shown) is disposed between the outer peripheral edge portion of the first case 24 and the opposing portion of the outer peripheral edge portion of the second case 26. The sealing material is also disposed between the portion of the side wall 30 where the opening 30 a is formed and the opposing portion of the connector 13. Furthermore, the sealing material is also disposed between the second case 26 and the opposing portion of the connector 13. As described above, the accommodation space 22 is watertightly sealed. In other words, the housing 20 has a waterproof structure.

  The circuit board 10 is fixed to at least one of the first case 24 and the second case 26 by screw fastening or the like. The housing 20 is not limited to the shape having the first case 24 and the second case 26. The housing 20 only needs to accommodate at least the circuit board 10.

  The surface 28a faces the one surface 12a in the Z direction. In the present embodiment, the direction from the surface 28a to the circuit board 10 in the Z direction substantially coincides with the direction of gravity. That is, the circuit board 10 is disposed on the surface 28a on the gravity direction side.

  The first case 24 is formed with a communication hole 32 that allows the accommodation space 22 and the external space 200 to communicate with each other. The external space 200 is a space outside the housing 20 and is a space around the housing 20. In other words, the external space 200 is a space in which the electronic device 100 is arranged. The back surface 28 b is in contact with the external space 200. The communication hole 32 is a through hole that penetrates the bottom portion 28 from the front surface 28a to the back surface 28b. The planar shape of the communication hole 32 is a substantially circular shape. It is also possible to adopt an example in which the planar shape of the communication hole 32 is a polygonal shape.

  When the electronic device 100 is arrange | positioned at an engine compartment, the temperature of the storage space 22 shall be 80 to 90 degreeC, for example. When the electronic device 100 is disposed in the vehicle interior, the temperature of the accommodation space 22 is, for example, 50 ° C. to 60 ° C.

  The filter device 40 prevents liquid from entering the accommodation space 22 from the external space 200 through the communication hole 32. As this liquid, rain water, water used for car washing, water rolled up when the vehicle travels, and the like are assumed. The filter device 40 prevents liquid from entering the accommodation space 22 and contacting the circuit board 10 with the liquid. Further, the filter device 40 enables ventilation between the accommodation space 22 and the external space 200 via the communication hole 32. The filter device 40 can also be referred to as a ventilation member or a waterproof member.

  As shown in FIGS. 2 to 4, the filter device 40 includes a filter 42, a filter case 44, and a seal ring 46. In FIG. 2, for the sake of convenience, the housing 20, the filter 42, and the filter case 44 are shown separated in the Z direction in order to clarify the structure of the filter device 40. The center of the communication hole 32, the filter 42, the filter case 44, and the seal ring 46 are substantially coincident with each other in the projection view in the Z direction. In FIG. 2, a line passing through the centers of the communication hole 32, the filter 42, the filter case 44, and the seal ring 46 is indicated by a broken line.

  The filter 42 is waterproof and breathable, and closes the communication hole 32 together with the filter case 44. That is, the filter 42 allows gas to pass and prevents liquid from passing. The filter 42 has water repellency and oil repellency. That is, the filter 42 is subjected to water repellent treatment and oil repellent treatment. Therefore, the filter 42 can also be called a water repellent filter or an oil repellent filter. The filter 42 can also be referred to as a gas permeable membrane.

  As shown in FIG. 5, the filter 42 has a plurality of holes. As the filter 42, for example, a porous film formed using a fluororesin or polyolefin can be employed. The diameter r of the hole in the filter 42 is, for example, 0.01 to 10 μm. The gas can pass through the holes in the filter 42. On the other hand, the liquid does not pass through the holes of the filter 42.

  A filter 42 is disposed in the filter case 44. The filter case 44 is disposed in the housing 20. The filter case 44 is formed with a plurality of ventilation paths through which the housing space 22 communicates with the external space 200. All the ventilation paths formed in the filter case 44 are closed by the filter 42. The filter case 44 is formed using, for example, a resin material. At least a part of the filter case 44 is disposed in a space surrounded by the communication hole 32.

  In the present embodiment, the filter case 44 is formed by injection molding. More specifically, molten resin is poured into a mold. The filter case 44 has a main body 48 and a lid 50.

  On the gravity direction side of the filter case 44, a heat generating component mounted on the one surface 12a or the back surface 12b is arranged. That is, in the Z direction projection view, the filter case 44 overlaps the heat generating component mounted on the one surface 12a or the back surface 12b.

  As shown in FIG. 3, the main body 48 is fixed to the housing 20. More specifically, the main body 48 is fixed in the vicinity of a portion of the bottom 28 where the communication hole 32 is formed. The filter 42 is disposed in the main body 48. As shown in FIGS. 2 to 4 and 6, the main body portion 48 includes an inner cylinder portion 48 a, an outer cylinder portion 48 b, and a rib 48 c. In FIG. 6, in order to clarify the structure of the main body 48, the main body 48 in a state where the lid 50 and the filter 42 are not arranged is shown. In FIG. 6, the inner hole 60a and the outer hole 60b are hatched to clarify the planar shapes of the inner hole 60a and the outer hole 60b.

  The inner cylinder part 48a forms the inner hole 60a as a ventilation path. The inner hole 60 a is a ventilation path for flowing air from the accommodation space 22 to the external space 200. The inner cylinder part 48a has a substantially cylindrical shape extending along the Z direction. An inner hole 60a is formed by the inner peripheral surface of the inner cylinder portion 48a. The planar shapes of the inner peripheral surface and the outer peripheral surface of the inner cylindrical portion 48a are substantially perfect circles. The inner cylinder part 48a is equivalent to the 1st cylinder part as described in a claim.

  The inner cylinder portion 48 a is inserted through the communication hole 32. A part of the inner cylindrical portion 48a is disposed in a space surrounded by the communication hole 32. In the projection view in the Z direction, the outer peripheral surface of the inner cylindrical portion 48 a is smaller in diameter than the communication hole 32 and is surrounded by the communication hole 32. Further, in the projection view in the Z direction, the centers of the inner peripheral surface and the outer peripheral surface of the inner cylindrical portion 48 a substantially coincide with the center of the communication hole 32.

  In the Z direction, one opening in the inner cylindrical portion 48 a is located on the accommodation space 22 side with respect to the bottom portion 28. On the other hand, in the Z direction, the other opening in the inner cylindrical portion 48 a is located on the outer space 200 side with respect to the bottom portion 28.

  The opening on the accommodation space 22 side in the inner cylindrical portion 48 a is provided on the opposite side to the direction of gravity with respect to the heat generating component of the circuit board 10. That is, the opening on the heat generating component side in the inner hole 60a is located on the side opposite to the direction of gravity with respect to the heat generating component. In other words, the electronic device 100 is assembled in the vehicle such that the opening on the heat generating component side in the inner hole 60a is located on the opposite side of the direction of gravity with respect to the heat generating component.

  The outer cylinder part 48b is arranged so as to surround the inner cylinder part 48a in the projection view in the Z direction. As shown in FIGS. 2, 3, and 6, the outer cylindrical portion 48b has a cylindrical portion 48d, a disk portion 48e, and a protruding portion 48f.

  The cylindrical portion 48d forms an outer hole 60b as a ventilation path. The outer hole 60 b is a ventilation path for flowing air from the external space 200 to the accommodation space 22. The cylindrical portion 48d has a substantially cylindrical shape extending along the Z direction. The cylindrical portion 48d surrounds the outer peripheral surface of the inner cylindrical portion 48a. An outer hole 60b is formed by the inner peripheral surface of the cylindrical portion 48d and the outer peripheral surface of the inner cylindrical portion 48a. The cylindrical portion 48d corresponds to the second cylindrical portion described in the claims.

  The planar shapes of the inner peripheral surface and the outer peripheral surface of the cylindrical portion 48d are substantially perfect circles. The cylindrical portion 48d is inserted through the communication hole 32. A part of the cylindrical portion 48d is disposed in a space surrounded by the communication hole 32. In the projection view in the Z direction, the outer peripheral surface of the cylindrical portion 48 d substantially coincides with the communication hole 32. Further, the center of the inner peripheral surface and the outer peripheral surface of the cylindrical portion 48 d substantially coincides with the center of the communication hole 32 in the projection view in the Z direction.

  In the Z direction, one end portion of the cylindrical portion 48d is located on the accommodation space 22 side with respect to the bottom portion 28. On the other hand, in the Z direction, the other end portion of the cylindrical portion 48d is located on the outer space 200 side with respect to the bottom portion 28.

  The opening on the side of the accommodation space 22 in the cylindrical portion 48d is provided on the side opposite to the direction of gravity with respect to the heat generating component of the circuit board 10. That is, the opening on the heat generating component side in the outer hole 60b is located on the side opposite to the direction of gravity with respect to the heat generating component. In other words, the electronic device 100 is assembled in the vehicle so that the opening on the heat generating component side in the outer hole 60b is located on the opposite side to the direction of gravity with respect to the heat generating component.

  Both the outer hole 60b and the inner hole 60a extend in the Z direction. The outer hole 60b does not intersect the inner hole 60a. In other words, the outer hole 60b does not communicate with the inner hole 60a.

  The end of the inner cylinder portion 48a on the side of the accommodation space 22 is shorter than the end of the cylindrical portion 48d on the side of the accommodation space 22 with respect to the heat generating component or the circuit board 10. In other words, the opening on the heat generating component side in the inner hole 60a has a shortest distance to the heat generating component or the circuit board 10 compared to the opening on the heat generating component side in the outer hole 60b. Therefore, the opening on the heat generating component side in the inner hole 60a is located on the gravity direction side with respect to the opening on the heat generating component side in the outer hole 60b.

  A filter 42 is disposed at the end of the inner cylindrical portion 48a, the rib 48c, and the cylindrical portion 48d on the outer space 200 side. The disk part 48e extends from the end of the cylindrical part 48d on the outer space 200 side in a direction perpendicular to the Z direction and from the inner periphery to the outer periphery of the cylindrical part 48d. As shown in FIG. 6, the planar shape of the disk portion 48 e is a substantially annular shape. The planar shapes of the inner peripheral end and the outer peripheral end of the disk portion 48e are substantially perfect circles.

  The disc part 48e is arranged on the external space 200 side with respect to the bottom part 28 in the Z direction. The connecting portion between the disk portion 48e and the cylindrical portion 48d is provided at substantially the same position as the end portion on the outer space 200 side in the inner cylindrical portion 48a in the Z direction.

  The rib 48c connects the inner cylindrical portion 48a and the cylindrical portion 48d. That is, the rib 48c connects the inner cylinder part 48a and the outer cylinder part 48b. The inner cylinder part 48a can be arrange | positioned in the position away from the cylindrical part 48d by the rib 48c. The rib 48c extends from a part of the connecting portion between the disk portion 48e and the cylindrical portion 48d toward the outer peripheral surface of the inner cylindrical portion 48a. Thus, the rib 48c forms a part of the opening of the outer hole 60b. The rib 48c is formed at substantially the same position as the disk portion 48e in the Z direction. The length of the rib 48c in the Z direction is shorter than the length of the cylindrical portion 48d in the Z direction. In the present embodiment, the filter case 44 has three ribs 48c. In the projection view in the Z direction, the three ribs 48c surround the inner cylindrical portion 48a.

  In the present embodiment, the number of filters 42 in the filter device 40 is one. One filter 42 is in contact with a connection portion between the disk portion 48e and the cylindrical portion 48d and an end portion on the outer space 200 side in the inner cylinder portion 48a, and is an opening on the outer space 200 side in the inner hole 60a and the outer hole 60b. It is arranged to block both. The filter 42 is fixed to the filter case 44 by welding or an adhesive material.

  In the projection view in the Z direction, the outer peripheral end of the disk portion 48 e is larger than the filter 42 and surrounds the filter 42. Therefore, the surface of the disk portion 48e opposite to the bottom portion 28 has a portion where the filter 42 is disposed and a portion where the filter 42 is not disposed.

  The disk portion 48e is formed with a groove 48g that prevents the water in the external space 200 from flowing into the filter 42. The groove 48g is recessed in the Z direction from the surface of the disk part 48e opposite to the bottom part 28. That is, the groove 48g is recessed in the direction of gravity from the surface of the disk part 48e opposite to the bottom part 28. The planar shape of the groove 48g is a substantially annular shape in which the inner peripheral end and the outer peripheral end form a substantially perfect circle shape. In the projection view in the Z direction, the groove 48g surrounds a portion where the filter 42 is disposed.

  The surface on the bottom 28 side of the disk portion 48e holds the seal ring 46 together with the back surface 28b. That is, the disk portion 48e is disposed on the opposite side of the back surface 28b with respect to the seal ring 46.

  The protrusion 48 f is provided to fix the main body 48 to the bottom 28. The protrusion 48f extends from a part of the outer peripheral surface of the cylindrical portion 48d in a direction orthogonal to the Z direction and from the inner periphery to the outer periphery in the cylindrical portion 48d.

  The main body 48 has three protrusions 48f. In the projection view in the Z direction, the communication hole 32 is surrounded by three protrusions 48f. The surface on the bottom 28 side of the protrusion 48f is in contact with the surface 28a. In the Z direction, the projecting portion 48f holds the bottom portion 28 and the seal ring 46 together with the disc portion 48e.

  The cylindrical portion 48d has a notch 48h at a location different from the location where the projection 48f is provided. When the main body 48 is disposed in the housing 20, the inner cylindrical portion 48 a and the cylindrical portion 48 d are inserted into the communication hole 32. At this time, the cylindrical part 48d can be made small by forming the notch 48h. After the main body portion 48 is disposed in the housing 20, the cylindrical portion 48 d returns to the size before being inserted into the communication hole 32. As described above, the main body 48 can be disposed in the housing 20.

  The lid 50 forms a ventilation path while covering the filter 42. The lid part 50 can also be called a cover or a cap. The lid 50 is fixed to the main body 48. The lid 50 is disposed on the opposite side of the housing space 22 with respect to the main body 48 in the Z direction. That is, the lid 50 and the main body 48 are arranged side by side in the Z direction. The entire lid portion 50 is disposed on the outer space 200 side with respect to the bottom portion 28.

  The lid part 50 includes a cylindrical part 50a, a first ceiling part 50b, a connection part 50c, a second ceiling part 50d, and a pillar part 50e. The cylindrical part 50a, the first ceiling part 50b, the connection part 50c, the second ceiling part 50d, and the pillar part 50e are connected to each other.

  The cylindrical portion 50a has a substantially cylindrical shape extending in the Z direction, and the planar shape of the inner peripheral surface and the outer peripheral surface thereof has a substantially perfect circle shape. The cylindrical portion 50a is disposed on the side opposite to the inner cylindrical portion 48a with respect to the filter 42. The end of the cylindrical portion 50 a on the filter 42 side is in contact with the filter 42. In the projection view in the Z direction, the inner peripheral surface of the cylindrical portion 50a substantially coincides with the inner peripheral surface of the inner cylindrical portion 48a. As described above, the space surrounded by the cylindrical portion 50 a communicates with the inner hole 60 a through the filter 42. Further, in the projection view in the Z direction, the outer peripheral surface of the cylindrical portion 50a substantially coincides with the outer peripheral surface of the inner cylindrical portion 48a.

  The first ceiling part 50b extends from the end of the cylindrical part 50a on the outer space 200 side in a direction orthogonal to the Z direction and from the inner periphery to the outer periphery of the cylindrical part 50a. In the Z direction, the first ceiling portion 50b faces the filter 42 and the disk portion 48e with a predetermined distance. In the projection view in the Z direction, a part of the first ceiling part 50 b overlaps a part of the filter 42. The planar shape of the first ceiling portion 50b is a substantially annular shape in which the planar shapes of the inner peripheral end and the outer peripheral end are substantially circular. In the projection view in the Z direction, the outer peripheral end of the disk portion 48e is surrounded by the outer peripheral end of the first ceiling portion 50b.

  The connection part 50 c is for connecting the lid part 50 to the main body part 48. The connection portion 50c extends from the outer peripheral end of the first ceiling portion 50b in the XY plane toward the bottom portion 28 in the Z direction. The lid part 50 has three connection parts 50c. At the outer peripheral end of the first ceiling portion 50b, a portion where the connection portion 50c is extended and a portion where the connection portion 50c is not extended are formed. In the projection view in the Z direction, the three connection parts 50c surround the disk part 48e. The side surface of the connecting portion 50c is in contact with the surface of the disk portion 48e opposite to the cylindrical portion 48d. In the Z direction, the end portion on the bottom portion 28 side of the connection portion 50c is located closer to the bottom portion 28 than the surface on the bottom portion 28 side of the disk portion 48e.

  A claw is formed at the end of each connecting portion 50c on the bottom 28 side. The claw extends from the end of the connection portion 50c on the bottom 28 side in a direction orthogonal to the Z direction and toward the inner hole 60a. In other words, the claw of the connection portion 50 c extends from the end portion on the bottom portion 28 side in a direction orthogonal to the Z direction and toward the seal ring 46. Note that the connecting portion 50 c is not in contact with the seal ring 46. The claw of the connection part 50c is in contact with the surface on the bottom part 28 side of the disk part 48e. The lid part 50 is fixed to the main body part 48 by the claw of the connection part 50c.

  Hereinafter, a space surrounded by the cylindrical part 50a, the first ceiling part 50b, the connection part 50c, and the disk part 48e is referred to as an outer path 60c. The outer path 60 c is a ventilation path for flowing air from the external space 200 to the accommodation space 22. The opening on the accommodation space 22 side in the outer path 60 c is closed by the filter 42. The outer path 60 c communicates with the outer hole 60 b through the filter 42. The outer path 60c communicates with the outer space 200. The opening on the outer space 200 side in the outer path 60c is formed by a portion where the connection portion 50c at the outer peripheral end of the first ceiling portion 50b is not extended. The outer hole 60b and the outer path 60c correspond to the second path described in the claims.

  The second ceiling portion 50d is disposed on the opposite side of the filter 42 with respect to the cylindrical portion 50a and the first ceiling portion 50b. The second ceiling part 50d is opposed to the cylindrical part 50a and the first ceiling part 50b with a predetermined distance in the Z direction. The second ceiling portion 50d has a substantially flat plate shape whose thickness direction is along the Z direction. The planar shape of the second ceiling portion 50d has a substantially perfect circle shape. In the projection view in the Z direction, the center of the second ceiling portion 50d substantially coincides with the center of the cylindrical portion 50a. In the projection view in the Z direction, a portion of the second ceiling portion 50d overlaps the entire cylindrical portion 50a. In other words, the second ceiling part 50d surrounds the outer peripheral surface of the cylindrical part 50a in the projection view in the Z direction.

  The column part 50e connects the first ceiling part 50b and the second ceiling part 50d. The column part 50e is extended in the Z direction. The column part 50e is extended in the Z direction from the outer peripheral end of the second ceiling part 50d in the XY plane to the first ceiling part 50b. The lid part 50 has three pillar parts 50e. At the outer peripheral end of the second ceiling portion 50d, a portion where the connection portion 50c is extended and a portion where the column portion 50e is not extended are formed. In the projection view in the Z direction, the three columnar parts 50e surround the cylindrical part 50a.

  Hereinafter, a space surrounded by the cylindrical portion 50a, the first ceiling portion 50b, the second ceiling portion 50d, and the pillar portion 50e is referred to as an inner path 60d. The inner path 60d is a ventilation path for flowing air from the accommodation space 22 to the external space 200. The opening on the accommodation space 22 side in the inner path 60d is closed by the filter 42. The inner path 60d communicates with the inner hole 60a through the filter 42. The inner path 60d is in communication with the outer space 200. The opening on the outer space 200 side in the inner path 60d is formed by a portion where the column part 50e is not extended at the outer peripheral end of the second ceiling part 50d.

  The inner path 60d does not intersect the outer hole 60b and the outer path 60c. In other words, the inner path 60d does not intersect the outer hole 60b and the outer path 60c. In other words, the inner path 60d does not communicate with the outer hole 60b and the outer path 60c. Similarly, the outer path 60c does not intersect the inner hole 60a and the inner path 60d. The inner hole 60a and the inner path 60d correspond to the first path described in the claims.

  The connecting portion between the cylindrical portion 50a and the first ceiling portion 50b is located closer to the second ceiling portion 50d than the other portions in the first ceiling portion 50b in the Z direction. In other words, the peripheral edge of the opening on the opposite side of the filter 42 in the cylindrical portion 50a is located closer to the second ceiling portion 50d than the first ceiling portion 50b in the Z direction. According to this, it can suppress that the water which entered the inner side path | route 60d from the external space 200 enters into the space which the cylindrical part 50a encloses, and can also suppress flowing into the filter 42 by extension.

  The seal ring 46 prevents liquid from passing between the filter case 44 and the bottom portion 28. That is, the seal ring 46 is provided for waterproofing. The seal ring 46 is formed using, for example, a rubber material. The seal ring 46 can also be referred to as an O-ring.

  A through hole extending in the Z direction is formed in the seal ring 46. In the projection view in the Z direction, the inner peripheral end of the seal ring 46 substantially coincides with the inner peripheral end of the communication hole 32. The seal ring 46 is disposed between the filter case 44 and the housing 20 and is in contact with the filter case 44 and the housing 20. More specifically, the seal ring 46 is disposed between the back surface 28b and the disk portion 48e, and is in contact with the back surface 28b and the disk portion 48e.

  After being assembled to the housing 20, the seal ring 46 is deformed as compared to before being assembled to the housing 20. Specifically, the seal ring 46 is deformed so that the width in the Z direction becomes small after being assembled to the housing 20. Thereby, the seal ring 46 suppresses the formation of a gap between the back surface 28b and the disk portion 48e.

  Next, the flow of air flowing through the ventilation path of the filter case 44 will be described with reference to FIG. In addition, the white arrow of FIG. 3 has shown the flow of air.

  When the circuit board 10 starts driving, the temperature of the circuit board 10 rises. Thereby, the temperature around the circuit board 10 in the accommodation space 22 rises. Therefore, the temperature around the circuit board 10 in the accommodation space 22 is higher than the temperature in the external space 200.

  In the present embodiment in which the circuit board 10 includes the heat generating component, the temperature around the heat generating component is particularly increased. As the temperature rises, the atmospheric pressure increases. Air flows from a space having a high atmospheric pressure toward a space having a low atmospheric pressure.

  Air also decreases in density as the temperature rises. Low density air is lighter than high density air. Therefore, the air that has become lighter as the temperature rises due to the driving of the circuit board 10 proceeds to the opposite side to the direction of gravity. According to the above, the air around the heat generating component disposed on the gravity direction side of the filter device 40 advances toward the filter device 40 by driving the circuit board 10.

  On the other hand, the opening on the heat generating component side in the inner hole 60a is shorter than the opening on the heat generating component side in the outer hole 60b. Therefore, the air whose temperature has been raised by the heat-generating component flows more easily into the inner hole 60a than the outer hole 60b. The air whose temperature has been increased by the heat generating component travels through the inner hole 60a in the direction opposite to the gravity direction. The high-temperature air flows from the inner hole 60a to the external space 200 through the filter 42 and the inner path 60d.

  By the way, the air around the heat generating component flows into the external space 200, so that the air pressure around the heat generating component is lowered. Therefore, the air in the external space 200 flows to the accommodation space 22 through the ventilation path of the filter case 44. At this time, in the inner hole 60a and the inner path 60d, since air flows toward the outer space 200, it is difficult for air to flow from the outer space 200 side to the accommodation space 22 side. On the other hand, in the outer hole 60b, the opening on the heat generating component side is farther from the heat generating component than the inner hole 60a. Therefore, in the outer hole 60b and the outer path 60c, air hardly flows from the accommodation space 22 to the outer space 200 as compared with the inner hole 60a and the inner path 60d.

  According to this, the air pressure of the air around the heat generating component decreases, so that the air in the external space 200 flows into the accommodation space 22 through the outer path 60c, the filter 42, and the outer hole 60b. Part of the air that has flowed into the accommodation space 22 through the outer hole 60b travels in a direction other than the gravitational direction. However, since the air pressure around the heat generating component is low, air that has traveled in a direction other than the direction of gravity also travels around the heat generating component. As described above, air having a relatively low temperature travels around the heat-generating component.

  According to the above, air whose temperature has been raised by the heat generating component flows from the accommodation space 22 to the external space 200, and air having a relatively low temperature flows from the external space 200 to the periphery of the heat generating component. These air flows can also be referred to as convection. The heat generating component is cooled by this convection.

  Next, effects of the electronic device 100 described above will be described.

  In the present embodiment, as described above, high-temperature air can flow from the periphery of the circuit board 10 to the external space 200, and low-temperature air can flow from the external space 200 to the periphery of the circuit board 10. it can. According to this, it can suppress that the circuit board 10 becomes high temperature.

  As described above, the air that has become lighter as a result of driving the circuit board 10 proceeds to the opposite side of the direction of gravity. On the other hand, the opening on the heat generating component side in the inner hole 60a is provided on the side opposite to the direction of gravity with respect to the heat generating component. According to this, the high temperature air around the heat generating component easily flows to the external space 200 through the inner hole 60a and the inner path 60d.

  Since air tends to flow from the periphery of the heat generating component to the filter device 40, the air pressure around the heat generating component is likely to decrease. Therefore, the air in the external space 200 easily flows to the periphery of the heat generating component through the outer path 60c and the outer hole 60b. According to the above, it is easy to flow high temperature air from the periphery of the heat generating component to the external space 200, and low temperature air easily flows from the external space 200 to the periphery of the heat generating component. Therefore, it is possible to effectively suppress the temperature of the heat generating component from rising.

  By the way, the filter apparatus 40 has the some filter 42, and the structure which each filter 42 obstruct | occludes one ventilation path is considered. In contrast to this configuration, in the present embodiment, the filter device 40 has one filter 42 that closes all the ventilation paths formed in the filter case 44. According to this, the process of arranging the filter 42 in the filter case 44 can be simplified.

  When corners are formed in the mold for molding the filter case 44, stress is likely to concentrate on the corners when the molten resin is poured into the mold. On the other hand, in this embodiment, both the inner cylinder part 48a that forms the inner hole 60a and the cylindrical part 48d that forms the outer hole 60b in the main body part 48 have a substantially cylindrical shape. According to this, the corners are formed in the mold as compared with the configuration in which the planar shape of the inner peripheral surface and the outer peripheral surface of the portion forming the inner hole 60a and the outer hole 60b in the main body portion 48 is a polygonal shape. Can be suppressed. Therefore, in the metal mold | die for shape | molding the filter case 44, it can suppress that stress concentrates on a specific location and can suppress deterioration of a metal mold | die.

(Second Embodiment)
In the present embodiment, the description of the parts common to the electronic device 100 shown in the first embodiment is omitted.

  In the present embodiment, as shown in FIGS. 7 and 8, the filter case 44 is formed of the same member as the housing 20. Specifically, the main body 48 is formed of the same member as the first case 24. The main body 48 and the first case 24 are formed using a resin material. The lid 50 is formed of a member different from the main body 48 and the first case 24.

  The outer cylindrical portion 48b of the filter case 44 has a substantially cylindrical shape extending from the bottom portion 28 toward the accommodation space 22 in the Z direction. The connecting portion between the outer cylindrical portion 48b and the bottom portion 28, where the filter 42 is disposed, is located on the opposite side to the gravity direction with respect to the back surface 28b. Thereby, it is possible to suppress the water that has entered the outer path 60 c from the external space 200 from flowing into the filter 42.

  In addition, in the bottom part 28 of this embodiment, the communication hole 32 shown in 1st Embodiment is not formed. In the present embodiment, the filter device 40 does not have the seal ring 46.

  The connection part 50 c is connected to the bottom part 28. For example, a structure that is snap-fit connected to the connection portion 50 c is formed on the bottom portion 28. Moreover, the structure by which the connection part 50c is fixed to the bottom part 28 via an adhesive material can also be employ | adopted.

  In the present embodiment, the step of arranging the main body 48 in the first case 24 can be omitted with respect to the configuration in which the main body 48 is a separate member from the first case 24. In the present embodiment, the seal ring 46 provided between the filter case 44 and the housing 20 can be omitted. Therefore, the cost applied to the seal ring 46 can be suppressed, and the process of arranging the seal ring 46 can be simplified.

  The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  In the above-described embodiment, the main body portion 48 has the example including the inner cylinder portion 48a, the outer cylinder portion 48b, and the rib 48c, but is not limited thereto. Moreover, in the said embodiment, although the cover part 50 showed the example which has the cylindrical part 50a, the 1st ceiling part 50b, the connection part 50c, the 2nd ceiling part 50d, and the pillar part 50e, It is not limited.

  In the above embodiment, the length of the rib 48c in the Z direction is shorter than the length of the cylindrical portion 48d in the Z direction, but is not limited thereto. The length of the rib 48c in the Z direction may be substantially equal to the length of the cylindrical portion 48d in the Z direction. In this example, the outer hole 60 b is divided by the rib 48 c, and three outer holes 60 b are formed in the main body portion 48.

  Although the circuit board 10 which has the board | substrate 12 and the electronic component 14 in the said embodiment was arrange | positioned in the accommodation space 22, the example was not limited to this. It is sufficient that at least a heat generating member that generates heat when energized is disposed in the accommodation space 22. An example in which only an electronic component such as a sensor is arranged in the housing 20 can also be adopted. In this example, the opening on the electronic component side in the inner hole 60a is shorter than the opening on the electronic component side in the outer hole 60b. In this example, the electronic component corresponds to the heat generating member described in the claims.

  Further, an example in which a plurality of heat generating members are arranged in the accommodation space 22 can be adopted. In this example, the opening on the housing space 22 side in the inner hole 60a is shorter than the opening on the housing space 22 side in the outer hole 60b in the shortest distance to the heating member closest to the filter device 40 among the plurality of heating members. Has been.

DESCRIPTION OF SYMBOLS 10 ... Circuit board, 12 ... Board | substrate, 12a ... One side, 12b ... Back surface, 13 ... Connector, 14 ... Electronic component, 20 ... Housing, 22 ... Storage space, 24 ... 1st case, 26 ... 2nd case, 28 ... Bottom portion, 28a ... front surface, 28b ... back surface, 30 ... side wall portion, 32 ... communication hole, 40 ... filter device, 42 ... filter, 44 ... filter case, 46 ... seal ring, 48 ... main body portion, 48a ... inner cylinder portion, 48b ... outer cylinder part, 48c ... rib, 48d ... cylindrical part, 48e ... disc part, 48f ... projection part, 48g ... groove, 48h ... notch, 50 ... lid part, 50a ... cylindrical part, 50b ... first ceiling part , 50c ... connection part, 50d ... second ceiling part, 50e ... pillar part, 60a ... inner hole, 60b ... outer hole, 60c ... outer path, 60d ... inner path, 100 ... electronic device, 200 ... outer space

Claims (12)

A heating member (10);
A housing (20) in which the heat generating member is housed in a housing space (22), and the housing space is watertightly sealed;
A filter device (40) that is provided in the housing and prevents the liquid in the external space (200) from entering the storage space and allows ventilation between the storage space and the external space;
With
The filter device has a filter case (44) in which a plurality of ventilation paths for allowing the accommodation space to vent from the external space are formed, and has waterproofness and air permeability, and is disposed in the filter case. A filter (42) for closing the ventilation path,
In the filter case, a first path (60a, 60d) and a second path (60b, 60c) formed so as not to intersect the first path are formed as the ventilation path,
The electronic device in which the opening on the heat generating member side in the first path is shorter in the shortest distance to the heat generating member than the opening on the heat generating member side in the second path.   The electronic device according to claim 1, wherein the filter device includes one filter that closes all the ventilation paths formed in the filter case. The housing is formed with a communication hole (32) for communicating the accommodation space and the external space.
The electronic device according to claim 1, wherein the filter case is formed of a member different from the casing, and at least a part thereof is disposed in a space surrounded by the communication hole and is fixed to the casing. .   The electronic device according to claim 1, wherein the filter case is formed of the same member as the housing.   The said filter case has a main-body part (48) with which the said filter was arrange | positioned while being provided in the said housing | casing, and a cover part (50) fixed to the said main-body part and covering the said filter. The electronic device according to any one of 1 to 4. Each of the main body part and the lid part is formed with both the first path and the second path,
The main body is
A first cylindrical portion (48a) having a cylindrical shape and forming the first path by an inner peripheral surface;
A cylindrical shape surrounding the outer peripheral surface of the first cylindrical portion, a second cylindrical portion (48d) that forms the second path by the inner peripheral surface;
The electronic device according to claim 5, comprising: The housing space (22) is provided in the housing (20) for housing the heat generating member (10) in the watertight sealed space (22), and the liquid in the external space (200) is prevented from entering the housing space, and And a filter device that allows ventilation between the external space and
A filter case (44) having a plurality of ventilation paths through which the accommodation space ventilates the external space;
A filter (42) having waterproofness and air permeability, disposed in the filter case, and closing all the air passages;
In the filter case, a first path (60a, 60d) and a second path (60b, 60c) formed so as not to intersect the first path are formed as the ventilation path,
The filter device in which the opening on the heat generating member side in the first path is shorter than the opening on the heat generating member side in the second path.   The filter device according to claim 7, comprising one filter that closes all the ventilation paths formed in the filter case. The housing is formed with a communication hole (32) for communicating the accommodation space and the external space.
The filter device according to claim 7 or 8, wherein the filter case is formed of a member different from the casing, and at least a part thereof is disposed in a space surrounded by the communication hole and is fixed to the casing. .   The filter device according to claim 7 or 8, wherein the filter case is formed of the same member as the casing.   The said filter case has a main-body part (48) with which the said filter was arrange | positioned while being provided in the said housing | casing, and a cover part (50) fixed to the said main-body part and covering the said filter. The filter device according to any one of 7 to 10. Each of the main body part and the lid part is formed with both the first path and the second path,
The main body is
A first cylindrical portion (48a) having a cylindrical shape and forming the first path by an inner peripheral surface;
A cylindrical shape surrounding the outer peripheral surface of the first cylindrical portion, a second cylindrical portion (48d) that forms the second path by the inner peripheral surface;
The filter device according to claim 11.

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