JP7084180B2 - Radar device - Google Patents

Description

The present invention relates to, for example, a small radar device mounted on a vehicle.

Conventionally, a small radar device such as a vehicle-mounted radar device has been used in which an antenna board having an antenna portion for transmitting and receiving radio waves is provided on the surface inside a housing composed of an upper case and a lower case. There is.

For example, the antenna device (radar device) described in Patent Document 1 is one of them, but the antenna board is held inside the housing by a shield member made of a conductive member for the purpose of preventing noise from the antenna board. there were.

In such a radar device, the upper case arranged in front of the irradiation direction of the radar is called a radome, and although it constitutes the irradiation surface of the radar, the distance between the antenna portion that transmits and receives radio waves and the radome, that is, the antenna substrate and the above. The radar irradiation performance differs depending on the distance from the upper case. However, for example, when the antenna substrate is held by a shield member inside the housing composed of the upper case and the lower case as in the radar device described in Patent Document 1, the upper case and the antenna constituting the radome are used. It was difficult to set the distance from the board accurately.

Japanese Unexamined Patent Publication No. 2006-22746

In view of the above-mentioned problems, it is an object of the present invention to provide a radar device capable of accurately arranging an antenna substrate on an upper case constituting a radome.

In the present invention, an antenna board having an antenna portion for transmitting and receiving radio waves on the surface, an upper case covering the antenna board at a predetermined distance from the surface of the antenna board, and a back surface side of the antenna board are designated. It is composed of a lower case that covers the upper case and the lower case, and the lower case is composed of a conductive member having conductivity. In the upper case and the lower case, the said The radar device is characterized in that a sandwiching portion is provided at a position facing the front and back directions, which is the thickness direction of the antenna board, to sandwich and fix the substrate edge portion of the antenna board in the front and back directions.

According to the present invention, the antenna substrate can be accurately arranged with respect to the upper case constituting the radome.
More specifically, the front and back sides of an upper case in which an antenna portion for transmitting and receiving radio waves covers the surface of an antenna substrate provided on the front surface at a predetermined interval, and a lower case in which the back surface side of the antenna substrate is covered at a predetermined interval. Since a sandwiching portion for sandwiching and fixing the substrate edge portion of the antenna board in the front and back directions is provided at a position facing the direction, the sandwiching portion is formed by assembling the upper case and the lower case to form the housing. The antenna board can be assembled to the housing by sandwiching the board edge portion of the antenna board in the front and back directions.

In the assembled state of the upper case and the lower case, the radome is fixed by sandwiching the substrate edge portion of the antenna board in the front and back directions with the sandwiching portions provided at the positions facing the upper case and the lower case in the front and back directions. The antenna board can be placed accurately with respect to the upper case constituting the above.

Further, since the lower case is made of a conductive member having conductivity, the lower case functions as a shield member for preventing noise, and the upper case constituting the radome and the lower case constituting the shield member are used. A housing that can prevent noise can be configured. Therefore, the radar device can be configured with a smaller number of parts than the conventional radar device in which the antenna substrate is held by the shield member inside the housing composed of the upper case and the lower case.

Further, since the substrate edge portion of the antenna substrate is sandwiched between the sandwiching portion of the lower case which is composed of a conductive member and functions as a shield member and the sandwiching portion of the upper case, the lower case and the antenna substrate which function as a shield member are sandwiched. Since the antennas and the antennas are surely in contact with each other so that they can be energized, the noise prevention effect as a shield member can be surely exhibited.

As an aspect of the present invention, the distance between the sandwiched portions in the front-back direction may be smaller than the thickness in the front-back direction of the antenna substrate.
According to the present invention, the substrate edge portion of the antenna substrate can be sandwiched between the sandwiching portions without any play. Therefore, the antenna substrate can be arranged with higher accuracy with respect to the upper case constituting the radome.
Further, since the lower case functioning as the shield member and the antenna substrate are in closer contact with each other, the noise prevention effect as the shield member can be improved.

Further, as an aspect of the present invention, the upper case may be provided with a position regulating means for regulating the position of the antenna substrate with respect to the upper case in the in-plane direction.
According to the present invention, since the position of the antenna board in the in-plane direction can be restricted with respect to the upper case, the board edge portion of the antenna board can be reliably sandwiched and fixed by the sandwiching portion between the upper case and the lower case. ..

Further, as an aspect of the present invention, the upper case may be provided with a board mounting portion for mounting the antenna board.
According to the present invention, the antenna board can be attached to the upper case, and when the upper case and the lower case are assembled to form the housing, the antenna board attached to the upper case is sandwiched between the lower case and fixed. Can be done. That is, since the antenna board is attached to the upper case in advance, the antenna board can be arranged with high accuracy with respect to the upper case constituting the radome.

Further, as an embodiment of the present invention, a pivot portion for pivotally supporting the antenna substrate is provided on the upper case, and an elastic locking portion for elastically deforming and locking the antenna substrate pivoted by the pivot portion is provided. The elastic locking portion may be used to form the substrate mounting portion.

According to the present invention, the antenna board can be easily attached to the upper case.
More specifically, the antenna substrate is pivotally supported by the pivot portion with respect to the upper case, and the antenna substrate pivoted by the pivot portion is locked by the elastic locking portion that elastically deforms, so that the antenna is attached to the upper case. The board can be easily attached.

Further, as an aspect of the present invention, a fixing portion for fixing the upper case and the lower case in the front-back direction may be provided outside the radio wave influence range of the antenna portion on the antenna board.
According to the present invention, the upper case and the lower case can be easily and surely assembled to form a housing, and a fixing portion for fixing the assembled state of the upper case and the lower case is provided outside the radio wave influence range of the antenna portion. Therefore, there is no problem in transmitting and receiving radio waves by the antenna unit. Therefore, it is possible to easily configure a radar device having high radio wave transmission / reception performance.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a radar device capable of accurately arranging an antenna substrate on an upper case constituting a radome.

Perspective view of the radar unit. An exploded perspective view of the radar unit. Vertical cross-sectional view of the radar device. Cross-sectional view of the radar device. An exploded perspective view of the radar device. An exploded perspective view of the radar device. Bottom view of the upper case. Explanatory drawing of the lower case. Explanatory drawing of the antenna board. A perspective view of the antenna board assembled to the upper case. Explanatory drawing explaining the assembly state of the antenna board to the upper case. Explanatory drawing explaining the assembly state of the antenna board to the upper case. Explanatory drawing explaining the assembly state of the lower case to the upper case. Bottom view of the upper case with the antenna board mounted.

1 is a perspective view of the radar unit 1, FIG. 2 is an exploded perspective view of the radar unit 1, FIG. 3 is a vertical cross-sectional view of the radar device 10 passing through the center of the width direction W, and FIG. 4 is FIG. AA cross-sectional view is shown, and FIGS. 5 and 6 show an exploded perspective view of the radar device 10.
More specifically, FIG. 5 is an exploded perspective view showing the front surface, a plane, and the right side surface of the radar device 10, and FIG. 6 is an exploded perspective view showing the front surface, the bottom surface, and the left side surface of the radar device 10.

7 shows a bottom view of the upper case 20, FIG. 8 shows an explanatory view of the lower case 30, FIG. 9 shows an explanatory view of the antenna board 40, and FIG. 10 shows a state in which the antenna board 40 is assembled to the upper case 20. It is a perspective view which shows the front surface, the bottom surface, and the right side surface, and FIGS. 11 and 12 show explanatory views explaining the assembling state of the antenna substrate 40 to the upper case 20.

Specifically, FIG. 8 (a) shows a plan view of the lower case 30, FIG. 8 (b) shows a sectional view taken along the line BB of FIG. 8 (a), and FIG. 8 (c) shows C of FIG. 8 (a). -C sectional view is shown. 9 (a) shows a plan view of the antenna board 40, FIG. 9 (b) shows a bottom view of the antenna board 40, and FIG. 9 (c) is a vertical cross-sectional view of the antenna board 40 passing through the center of the width direction W. Is shown.

FIG. 11A shows a vertical cross-sectional view of the state before assembling the antenna board 40 to the upper case 20, and FIG. 11B shows a vertical cross-sectional view of the state where the antenna board 40 is started to be assembled to the upper case 20. 12 (a) shows a vertical cross-sectional view of the antenna board 40 inserted into the upper case 20, and FIG. 12 (b) shows a vertical cross-sectional view of the pivot state of the antenna board 40 into the upper case 20. There is.

Further, FIG. 13 shows an explanatory diagram illustrating a state in which the lower case 30 is assembled to the upper case 20, and FIG. 14 shows a bottom view of the upper case 20 on which the antenna substrate 40 is mounted.
Specifically, FIG. 13A shows a vertical cross-sectional view of the lower case 30 before being assembled to the upper case 20 to which the antenna board 40 is assembled, and FIG. 13B shows a vertical cross-sectional view of the same state. ..

The height direction of the radar device 10 (vertical direction in FIG. 1) is the vertical direction Z, and the width direction of the radar device 10 (the direction connecting the upper left and the lower right in FIG. 1) is the width direction W. The depth direction (the direction connecting the lower left and the upper right in FIG. 1) is the depth direction H. Further, in the depth direction H, the front side (lower left side in FIG. 1) is the depth direction front side Hf, and the depth side (upper right side in FIG. 1) is the depth direction rear side Hb.

The radar unit 1 is a small radar unit mounted on a vehicle, and as shown in FIGS. 1 and 2, a radar device 10 having a substantially rectangular shape in a plan view, which is longer in the depth direction H than the width direction W, and a radar device 10 are mounted on the vehicle. It is composed of a mounting bracket 2 for mounting at an appropriate position (not shown).

The mounting bracket 2 is a mounting member that detachably mounts the radar device 10 having a substantially rectangular shape in a plan view, and includes a mounting point 3 for mounting the radar device 10 and three mounting points 4 extending outward from the mounting point 3. It is composed of.

The radar device 10 mounted at a predetermined position on the vehicle by the mounting bracket 2 is composed of a housing 10a composed of an upper case 20 and a lower case 30, and an antenna substrate 40 arranged in the internal space 10b of the housing 10a. ing.

The upper case 20 constituting the upper half portion of the housing 10a is made of a resin that transmits radio waves, and has a peripheral portion 21 having a predetermined width and height that protrudes downward along a peripheral edge having a substantially rectangular shape in a plan view. And a cylindrical terminal cover portion 22 that protrudes outward from the short side portion of the front side Hf in the depth direction of the peripheral portion 21 having a rectangular shape in a plan view.

In the plan-view rectangular upper case 20, the front side Hf in the depth direction is the transmitting antenna portion 20a having a flat upper surface, and the rear side Hb in the depth direction protrudes in a substantially arcuate shape in the side view. Consists of. At the four corners of the upper case 20 in a plan view, fixing portions 23 for attaching the fixing bolts 60 to be fixed to the lower case 30 are provided.

The terminal cover portion 22 has a substantially rectangular cylinder shape that is horizontally long when viewed from the front, has a penetration space 221 that penetrates the inside and the outside of the upper case 20 in the depth direction H, and is fitted with another connector on the upper surface. A fitting fixing portion 222 is provided for fixing the fitting. The terminal cover portion 22 having a substantially rectangular tubular shape in front view is provided so that the lower half portion protrudes downward from the peripheral portion 21. Further, as shown in FIG. 11, the penetration space 221 is smaller than the fitting space 221a and the fitting space 221a into which other electrically connected connectors are fitted, and positions the terminal portion 42 of the antenna board 40 described later. It is composed of a position regulation space 221b to be regulated.

On the bottom surface side of the upper case 20, a circumferential fitting convex portion 24 projecting downward is provided inside the peripheral portion 21 in a plan view. The circumferential fitting convex portion 24 has a substantially V-shaped cross section as shown in the enlarged view of the a portion and the enlarged view of the b portion in FIG.

Further, as shown in FIGS. 4 and 7, on the bottom surface of the peripheral edge portion 21, a sandwiching portion 25 is provided so as to correspond to the receiving antenna portion 20b so as to project downward in a substantially frame shape on the bottom surface. The sandwiching portion 25 has a U-shaped bottom view with the front side Hf in the depth direction open, and is configured like a peripheral wall on the inside at a predetermined distance from the peripheral fitting convex portion 24.

Further, in the bottom view U-shaped sandwiching portion 25, a snap fit 26 corresponding to the elastic locking portion is provided at the center of the short side portion of the rear side Hb in the depth direction by cutting out a part thereof.

As shown in the enlarged view of the e portion of FIGS. 3 and 6, the snap-fit 26 has an elastic arm 27 extending downward from the bottom surface of the peripheral edge portion 21 and a locking protrusion protruding downward from the lower end of the elastic arm 27 to the front side Hf in the depth direction. It is composed of a part 28. The locking convex portion 28 is composed of an inclined surface 28a whose bottom surface side is inclined upward toward the front side Hf in the depth direction and a locking surface 28b whose upper surface is inclined upward toward the rear side Hb in the depth direction. .. The locking surface 28b is formed so as to be located below the lower end surface of the sandwiching portion 25 by the thickness of the antenna substrate 40 described later.

Further, as shown in the enlarged view of the f portion of FIG. 6 and FIG. 7, a vertically long rib 29 projecting inward in a plan view along the inner peripheral side of the peripheral edge portion 21 is provided. The ribs 29 are provided near both ends of the long side in the depth direction H of the peripheral portion 21 having a rectangular shape when viewed from the bottom, and are provided at four places in total.

The lower case 30 which is assembled with the upper case 20 to form the lower half portion of the housing 10a is formed of a rectangular shape in a plan view corresponding to the upper case 20, and has a predetermined height and width along the rectangular shape in a plan view. A peripheral edge portion 31 is provided. Further, a fitting recess 32 into which the terminal cover portion 22 is fitted is provided at the center of the short side of the front side Hf in the depth direction in the peripheral portion 31 having a rectangular shape in a plan view. Further, in the peripheral portion 31, the rectangular corners in a plan view are chamfered inward, and the four corners in a plan view outside the chamfered portion correspond to the fixing portion 23 and the fixing bolt 60 for fixing to the upper case 20. A fixing portion 33 for screwing is provided.

As shown in FIG. 8, a circumferential fitting convex portion 24 protruding downward from the vicinity of the peripheral edge portion of the upper case 20 is fitted near the center in the width direction of the peripheral edge portion 31 having a predetermined height and width. A fitting groove 34 having a U-shaped cross section is provided. As shown in the enlarged view of the portion a in FIG. 3, the fitting groove portion 34 is formed with a depth and a cross-sectional shape in which the lower end of the peripheral fitting convex portion 24 does not abut on the groove bottom portion when fitted. ing.

It should be noted that, in the peripheral portion 31 in which the fitting groove portion 34 is formed near the center in the width direction, the portion inside the fitting groove portion 34 in a plan view, the sandwiching portion 25 protruding downward from the bottom surface of the peripheral edge portion 21 in a substantially frame shape in the bottom view, and the upper and lower portions. It constitutes a sandwiching portion 35 that faces the direction and sandwiches the antenna substrate 40 from above and below.

The lower case 30 is made of a conductive member having conductivity so as to be in contact with the antenna substrate 40, which will be described later, so as to function as a shield member, and will be described later in the plan view inside from the sandwiching portion 35. A GND frame portion 36 formed in a desired frame shape that is in contact with a GND portion (not shown) that surrounds the outside of the antenna portion (not shown) of the antenna substrate 40 in a plan view is provided.

Further, among the short sides of the rectangular shape in a plan view, both sides of the fitting recess 32 on the short side of the front side Hf in the depth direction, the vicinity of the center of the long side of the rectangular shape in a plan view, and the bottom surface are projected outward and mounted brackets. A fixed convex portion 37 for fixing to 2 is provided.

The peripheral fitting convex portion 24 of the upper case 20 configured in this way is inserted into the fitting groove portion 34 of the lower case 30 to be fitted, and the upper case 20 and the lower case 30 are assembled to form the upper case 20 and the lower case 30. A housing 10a having an internal space 10b surrounded by and can be configured.

The antenna substrate 40 arranged in the internal space 10b of the housing 10a configured by assembling the upper case 20 and the lower case 30 has a predetermined thickness in which an antenna portion (not shown) for transmitting and receiving radio waves is provided on the surface. It is composed of a substrate 41, a terminal portion 42 protruding outward from the back surface side of the substrate 41, and a position holder 50 mounted on the terminal portion 42. The peripheral edge of the substrate 41 is the substrate peripheral edge 41a.

More specifically, the substrate 41 provided on the surface with an antenna portion (not shown) for transmitting and receiving radio waves is a printed circuit board that constitutes the antenna portion by a printed pattern (not shown), and has a rectangular shape in a plan view with chamfered corners. It is formed by.

A terminal support portion 411 projecting outward is provided at the center of the short side portion of the substrate 41 formed into a rectangular shape in a plan view with chamfered corners (that is, a portion corresponding to the terminal cover portion 22 in the upper case 20). ..

Further, as shown in FIG. 9, the rib 29 is fitted near both ends of the long side in the depth direction H of the substrate 41 formed in a substantially rectangular shape in a plan view, that is, at a position corresponding to the rib 29 of the upper case 20. A total of four notch recesses 412 are provided.

Further, on the side facing the terminal support portion 411, that is, at the center of the short side of the rear side Hb in the depth direction, a snap recess 413 into which the elastic arm 27 in the snap fit 26 of the upper case 20 is fitted is provided.

As shown in FIG. 9, the terminal portion 42 has a plurality of tabs 421 protruding outward (front side Hf in the depth direction) from the terminal support portion 411 along the back surface of the substrate 41 at predetermined intervals in the width direction W. The inside (rear side Hb in the depth direction) is penetrated in the thickness direction (vertical direction Z) of the substrate 41, and is electrically connected to the above-mentioned print pattern.

The terminal portion 42 configured in this way is inserted into the through space 221 inside the terminal cover portion 22 of the upper case 20 described above, and is electrically connected to the terminals of other connectors connected to the terminal cover portion 22. The cover. In this embodiment, the terminal portion 42 is composed of six tabs 421.

The position holder 50 mounted on the terminal portion 42 is a horizontally long block body having a long depth direction H and a long width direction W with respect to the vertical direction Z, and as shown in FIGS. 5, 6 and 9, the horizontally long block main body. It is composed of 51 and inclined convex portions 52 (52a, 52b) provided on the upper surface and the bottom surface of the block main body 51, respectively.

More specifically, the block main body 51 has a horizontally long substantially rectangular shape that is longer in the width direction W than the depth direction H and the vertical direction Z and longer in the depth direction H than the vertical direction Z, and each of the plurality of tabs 421 is in the depth direction. Insertion holes 511 in the depth direction H to be inserted into H are provided at predetermined intervals in the width direction W according to the number of tabs 421.

As shown in the enlarged view of the j portion of FIG. 9C, the inclined convex portions 52 provided on the upper surface and the bottom surface of the block main body 51 have an inclined surface 521 inclined with respect to the depth direction H and the vertical direction Z, and an inclined surface. It is a side view substantially one-sided inclined trapezoidal shape composed of a flat top portion 522 provided at the top of the top of 521. The inclined convex portion 52 formed in a side view substantially one-sided inclined trapezoidal shape by the inclined surface 521 and the flat top portion 522 is provided on the upper surface side of the block main body 51, and the upper inclined convex portion 52a protruding upward and the bottom surface side. There is a lower inclined convex portion 52b that protrudes downward in preparation for the above.

Although the upper inclined convex portion 52a provided on the upper surface of the block main body 51 and the lower inclined convex portion 52b provided on the bottom surface of the inclined convex portion 52 have the same shape, they are centered on the center of the side view of the block main body 51. It is arranged in a symmetrical direction from the side viewpoint.

Specifically, the inclined surface 521 of the upper inclined convex portion 52a provided on the upper surface of the block main body 51 is inclined in the inclined direction in which the vertical direction Z becomes lower toward the front side Hf in the depth direction, and the flat top portion 522 is rearward in the depth direction. While it is arranged on the side Hb, the inclined surface 521 of the lower inclined convex portion 52b provided on the bottom surface of the block main body 51 is inclined in the inclined direction in which the vertical direction Z becomes higher toward the rear side Hb in the depth direction. , The flat top 522 is arranged on the front side Hf in the depth direction. Therefore, the inclined surface 521 inclined at the front side Hf in the depth direction in the upper inclined convex portion 52a and the inclined surface 521 inclined at the rear side Hb in the depth direction in the lower inclined convex portion 52b are oriented in parallel to the side view. Therefore, the position holder 50 provided with the inclined convex portions 52a and 52b on the upper surface and the bottom surface of the block main body 51 can form a substantially parallel four-sided shape in the side view.

As shown in the enlarged view of the portion a in FIG. 3, in the position holder 50 constituting the side view substantially parallel quadrilateral shape, the flat top portion 522 and the lower inclined convex portion 52b of the upper inclined convex portion 52a are formed. The distance between the flat top portion 522 in the vertical direction Z (hereinafter referred to as the top distance D1) is the distance between the inner surfaces of the position restricting space 221b constituting the penetration space 221 of the terminal cover portion 22 in the vertical direction Z (hereinafter referred to as the space height Dh). The distance between the inclined surface 521 of the upper inclined convex portion 52a and the inclined surface 521 of the lower inclined convex portion 52b (hereinafter referred to as the inclined interval D2) is substantially the same, and the orientation is parallel to the side view. It is formed at intervals smaller than Dh.

Further, the inclined convex portions 52 formed in such a shape each have a thickness in the width direction W, but the upper inclined convex portions 52a arranged on the upper surface of the block main body 51 are separated by a predetermined interval in the width direction W3. Two lower inclined convex portions 52b arranged on the bottom surface of the block main body 51 are arranged at a predetermined interval in the width direction W. Therefore, in the plan view direction, the lower inclined convex portion 52b is arranged at the position of the bottom surface corresponding to the adjacent upper inclined convex portions 52a among the three arranged at a predetermined interval in the width direction W. ..

Subsequently, an assembling method for assembling the upper case 20, the lower case 30, and the antenna board 40 configured as described above to form the radar device 10 will be described.
First, the position holder 50 is attached to the terminal portion 42 mounted on the back surface of the substrate 41 to form the antenna substrate 40. At this time, the position holder 50 is inserted to a position where the end surface of the rear side Hb in the depth direction abuts on the end surface of the front side Hf in the depth direction of the terminal support portion 411 of the substrate 41.

Next, the antenna board 40 is assembled to the upper case 20. To assemble the antenna board 40 to the upper case 20, the antenna board 40 is mounted from below the upper case 20 as shown in FIGS. 10 and 11. Specifically, the antenna substrate 40 tilted so that the front side Hf in the depth direction is upward and the rear side Hb in the depth direction is downward, that is, the terminal portion 42 is upward is arranged below the upper case 20 (FIG. 11). (A)), the terminal portion 42 is inserted into the penetration space 221 of the terminal cover portion 22 from the inside of the bottom view (see FIG. 11B).

As for the tilt angle of the antenna substrate 40 at this time, as shown in the enlarged view of the k portion of FIG. 11A, the tilted surface 521 of the tilted convex portion 52 of the position holder 50 mounted on the terminal portion 42 is in the depth direction. It is tilted at an angle toward H, and the position holder 50 is inserted from the rear side Hb in the depth direction of the position restricting space 221b. At this time, since the antenna substrate 40 is tilted at the tilt angle, the tilted surface 521 faces the surface in the vertical direction Z constituting the position limiting space 221b. This state is called the insertion posture.

Then, as shown in FIG. 12A, the antenna substrate 40 is moved to the front side Hf in the depth direction while maintaining the insertion posture, that is, tilting the antenna substrate 40. At this time, since the antenna board 40 is tilted at the tilt angle, the position holder 50 attached to the terminal portion 42 of the antenna board 40 is also tilted, and the tilted surface 521 provides the position restricting space 221b as described above. It faces the constituent surface of the vertical direction Z. In this insertion posture state, the inclination interval D2 between the inclined surface 521 of the upper inclined convex portion 52a and the inclined surface 521 of the lower inclined convex portion 52b, which are oriented parallel to the side view, is larger than the space height Dh of the position restricting space 221b. Since the space is small, it is possible to smoothly move to the front side Hf in the depth direction.

In this way, the movement to the front side Hf in the depth direction is as shown in FIG. 12 (b) until the position holder 50 becomes the end portion of the front side Hf in the depth direction of the position restricting space 221b, that is, FIG. As shown in the above, the antenna substrate 40 is inserted to a predetermined position where the surface of the substrate 41 on the front side in the depth direction abuts on the inner surface of the peripheral surface portion 21 of the front side Hf in the depth direction of the upper case 20.

Next, as shown in FIG. 12B, the antenna board 40 inserted to a predetermined position is pivotally driven.
Specifically, the antenna substrate 40 is pivoted in the direction of moving the rear Hb in the depth direction upward with the position holder 50 inserted in the position restricting space 221b of the terminal cover portion 22 as the pivot center. At this time, one of the boundary portions between the inclined surface 521 and the flat top 522 in the upper inclined convex portion 52a and the lower inclined convex portion 52b provided on the position holder 50 mounted on the terminal portion 42 of the antenna board 40 is position-controlled. It comes into contact with the inner surface of the space 221b in the vertical direction Z, and is pivoted with the contact point as the pivot center.

Then, by pivoting the antenna board 40 with the position holder 50 as the pivot center, the snap fit 26 is locked to the snap recess 413 of the antenna board 40 and the antenna is mounted on the upper case 20 as shown in FIG. The board 40 can be attached.

More specifically, when the antenna board 40 is pivoted to the direction in which the board 41 is along the depth direction H, the elastic arm 27 is provided by the inclined surface 28a when the locking convex portion 28 of the snap fit 26 passes through the snap recess 413. Is elastically deformed to the rear side Hb in the depth direction, and the locking convex portion 28 passes through the snap recess 413, so that the locking convex portion 28 moves to the front side Hf in the depth direction by the urging force of the elastic arm 27 and is locked. The surface 28b is locked to the bottom surface side of the substrate 41.

In the locked state by the snap fit 26, the front side Hf in the depth direction of the antenna board 40 is fixed in position with respect to the terminal cover portion 22 by the position holder 50, and the rear side Hb in the depth direction of the antenna board 40 is the snap fit 26. That is, both sides of the antenna board 40 in the depth direction H are fixed to the antenna board 40.

Further, due to the pivot of the antenna substrate 40, the flat top portion 522 of the inclined convex portion 52 is the inner surface of the position restricting space 221b in the vertical direction Z from the insertion posture in which the inclined surface 521 faces the inner surface of the position restricting space 221b in the vertical direction Z. However, since the top spacing D1 between the flat tops 522 of the inclined convex portion 52 is substantially the same as the space height Dh in the position restricting space 221b of the penetration space 221 of the terminal cover portion 22, the penetration is performed. Position regulation of space 221 In space 221b, the terminal portion 42 can be accurately positioned and regulated without play.

Further, since the locking surface 28b constituting the locking convex portion 28 is formed so as to be located below the lower end surface of the sandwiching portion 25 by the thickness of the substrate 41, the upper surface of the substrate 41 is below the sandwiching portion 25. It will come into contact with the end face.

Further, as shown in FIG. 14, the antenna substrate 40, which is inserted to a predetermined position with respect to the terminal cover portion 22 and then pivoted as described above, is formed on the inner surface of the peripheral edge portion 21 on the bottom surface side of the upper case 20. The rib 29 can be assembled so as to fit into the notch recess 412 of the substrate 41. As a result, the antenna board 40 can be assembled with the positions of the depth direction H and the width direction W restricted with respect to the upper case 20.

As described above, the lower case 30 is assembled from below to the upper case 20 to which the antenna board 40 is assembled, and the fixing portions 23 and 33 are fastened with the fixing bolts 60 to complete the assembly of the radar device 10.
At this time, the circumferential fitting convex portion 24 projecting downward from the peripheral edge portion 21 of the upper case 20 is inserted into the fitting groove portion 34 formed in the peripheral edge portion 31 of the lower case 30, and the terminal cover is inserted in the fitting recess 32. It is assembled in such a manner that the portion 22 is fitted.

Further, as shown in the enlarged view of the c portion in FIG. 4, the rib 29 provided on the inner surface of the peripheral edge portion 21 is also inserted into the fitting groove portion 34 together with the circumferential fitting convex portion 24, so that the upper case 20 can be used. The lower case 30 can be assembled with the width direction W regulated.

Further, by assembling the upper case 20 and the lower case 30 to which the antenna board 40 is assembled with the upper surface in contact with the bottom surface of the sandwiching portion 25, as shown in the enlarged view of the c portion of FIG. 4, the upper case 20 The antenna board 40 can be mounted on the housing 10a composed of the upper case 20 and the lower case 30 so as to be sandwiched between the sandwiching portion 25 and the sandwiching portion 35 of the lower case 30 from both sides in the vertical direction Z.

As described above, the radar device 10 has an antenna substrate 40 having an antenna portion for transmitting and receiving radio waves on the surface thereof, an upper case 20 covering the surface of the antenna substrate 40 at a predetermined distance, and a back surface side of the antenna substrate 40. The lower case 30 is composed of a lower case 30 and the upper case 20 and the lower case 30 are used to form a housing 10a, and the lower case 30 is composed of a conductive member having conductivity. Since the sandwiching portions 25 and 35 for sandwiching and fixing the substrate peripheral portion 41a of the antenna substrate 40 in the vertical direction z are provided at the positions facing the vertical direction z in 30, the antenna substrate is provided with respect to the upper case 20 constituting the radome. 40 can be arranged accurately.

More specifically, the upper case 20 in which the antenna portion for transmitting and receiving radio waves covers the surface of the antenna substrate 40 provided on the surface at a predetermined interval, and the lower case 30 in which the back surface side of the antenna substrate 40 is covered at a predetermined interval. Since the sandwiching portions 25 and 35 for sandwiching and fixing the substrate peripheral portion 41a of the antenna substrate 40 in the vertical direction z are provided at the positions facing the vertical direction z, the upper case 20 and the lower case 30 case are assembled. By configuring the housing 10a, the board peripheral portion 41a of the antenna board 40 can be sandwiched in the vertical direction z by the sandwiching portions 25 and 35, and the antenna board 40 can be assembled to the housing 10a.

In the assembled state of the upper case 20 and the lower case 30, the sandwiching portions 25 and 35 provided in the upper case 20 and the lower case 30 facing each other in the vertical direction z are used to vertically rotate the substrate peripheral portion 41a of the antenna substrate 40. Since it is sandwiched and fixed in z, the antenna substrate 40 can be accurately arranged with respect to the upper case 20 constituting the radome.

Further, since the lower case 30 is made of a conductive member having conductivity, the lower case 30 is made to function as a shield member for preventing noise, and the upper case 20 constituting the radome and the lower case 30 constituting the shield member are used. A housing 10a capable of preventing noise can be configured. Therefore, the radar device 10 can be configured with a smaller number of parts than the conventional radar device in which the antenna substrate 40 is held by the shield member in the internal space 10b composed of the upper case 20 and the lower case 30.

Further, since the substrate peripheral edge portion 41a of the antenna substrate 40 is sandwiched between the sandwiching portion 35 in the lower case 30 which is composed of a conductive member and functions as a shield member and the sandwiching portion 25 of the upper case 20, the lower case functions as a shield member. Since the 30 and the antenna board 40 are in contact with each other so as to be able to be energized, the noise prevention effect as a shield member can be surely exhibited.

Further, the vertical z spacing of the sandwiching portions 25 and 35, that is, the vertical z spacing of the sandwiching portions 25 and 35 when the bottom surface of the peripheral edge portion 21 and the upper surface of the peripheral edge portion 31 abut is the upper and lower sides of the antenna substrate 40. Since it is smaller than the thickness in the direction z, the substrate peripheral edge portion 41a of the antenna substrate 40 can be sandwiched between the sandwiching portions 25 and 35 without any play. Therefore, the antenna substrate 40 can be arranged with higher accuracy with respect to the upper case 20 constituting the radome.
Further, since the lower case 30 functioning as the shield member and the antenna substrate 40 are in closer contact with each other, the noise prevention effect as the shield member can be improved.

Further, the upper case 20 is provided with a rib 29 that regulates the position of the antenna board 40 with respect to the upper case 20 in the depth direction H and the width direction W, so that the antenna board 40 has a depth direction H and a width with respect to the upper case 20. Since the position of the direction W can be regulated, the substrate peripheral edge portion 41a of the antenna substrate 40 can be reliably sandwiched and fixed by the sandwiching portions 25 and 35 between the upper case 20 and the lower case 30.

Further, by providing the upper case 20 with a snap fit 26 for attaching the antenna board 40, the antenna board 40 can be attached to the upper case 20, and the upper case 20 and the lower case 30 are assembled to form the housing 10a. At that time, the antenna board 40 attached to the upper case 20 can be sandwiched between the lower case 30 and fixed. That is, since the antenna board 40 is attached to the upper case 20 in advance, the antenna board 40 can be arranged with high accuracy with respect to the upper case 20 constituting the radome.

Further, a position holder 50 that pivotally supports the antenna board 40 is provided on the upper case 20, and a snap fit 26 that elastically deforms and locks the antenna board 40 pivotally driven by the position holder 50 is provided. Therefore, the antenna board 40 can be easily attached to the upper case 20.

More specifically, the antenna board 40 is pivotally supported by the position holder 50 with respect to the upper case 20, and the antenna board 40 pivotally driven by the position holder 50 is locked by the elastically deformable snap fit 26. The antenna board 40 can be easily attached to the 20.

Further, a terminal portion 42 protruding from the terminal support portion 411 of the substrate 41 is mounted on the antenna board 40, and a terminal cover portion 22 into which the terminal portion 42 is inserted is provided in the upper case 20 and is mounted on the terminal portion 42. A position holder 50 for holding the position of the terminal portion 42 in the terminal cover portion 22 is provided, and the position holder 50 is tilted so that the inclination interval D2 is smaller than the space height Dh of the position regulation space 221b of the terminal cover portion 22. The convex portion 52 is provided, the inclined convex portion 52 faces in the vertical direction Z, and the terminal portion 42 is inserted into the terminal cover portion 22 in an insertion posture that allows the terminal cover portion 22 to move in the depth direction H with respect to the terminal cover portion 22. Is mounted on the antenna board 40 by pivoting the antenna board 40 in a state where the antenna board 40 is inserted to a predetermined position and changing to a position holding posture for holding the position of the terminal part 42 in the terminal cover part 22. The antenna board 40 can be easily attached to the upper case 20 in a state where the terminal portion 42 protruding from the terminal support portion 411 of the board 41 is held at a predetermined position in the terminal cover portion 22.

More specifically, by attaching the position holder 50 to the terminal portion 42 mounted on the antenna board 40 and protruding from the terminal support portion 411 of the board 41, the terminal portion 42 is held in a predetermined position in the terminal cover portion 22. can do.

Further, the antenna board 40 can be pivotally attached to the upper case 20 with the position holder 50 attached to the terminal portion 42 as the pivot center.
Further, since the position holder 50 is provided with the inclined convex portion 52 whose inclination interval D2 is smaller than the space height Dh of the position restricting space 221b of the terminal cover portion 22, the inclined convex portion 52 faces the vertical direction Z. That is, the terminal portion 42 is inserted into the terminal cover portion 22 in the posture before the antenna board 40 is pivoted, and the antenna board 40 is pivoted in a state where the terminal portion 42 is inserted to a predetermined position with respect to the terminal cover portion 22. It can be moved and attached to the upper case 20.

The terminal portion 42 is inserted into the terminal cover portion 22 in a state where the inclined convex portion 52 faces in the vertical direction Z, that is, in a posture before pivoting the antenna substrate 40. In this state, the inclination interval D2 is the terminal cover. Since the inclined convex portion 52 smaller than the space height Dh of the position restricting space 221b of the portion 22 faces in the vertical direction Z, the position holder 50 interferes with the insertion in the terminal cover portion 22, and the position holder 50 is smoothly inserted. be able to.

Further, since the inclined convex portion 52 is formed in an inclined shape that is inclined with respect to the vertical direction Z and the depth direction H, the inclined convex portion 52 is formed by the inclined shape in the inserted state of the terminal portion 42 in which the inclined convex portion 52 faces the vertical direction Z. It can be inserted stably.

Further, the fixing portions 23 and 33 for fixing the upper case 20 and the lower case 30 in the vertical direction z with the fixing bolts 60 are outside the radio wave influence range of the antenna portion on the antenna board 40, that is, the transmitting antenna portion 20a and the receiving antenna portion. By being provided on the outside of the plan view of 20b, the upper case 20 and the lower case 30 can be easily and surely assembled to form the housing 10a, and the transmission and reception of radio waves by the antenna portion are not hindered. Therefore, it is possible to easily configure the radar device 10 having high radio wave transmission / reception performance.

In correspondence between the configuration of the present invention and the above-described embodiment, the antenna substrate of the present invention corresponds to the antenna substrate 40.
Similarly below
The upper case corresponds to the upper case 20
The lower case corresponds to the lower case 30
The housing corresponds to the housing 10a and
The sandwiching portion corresponds to the sandwiching portion 25 and the sandwiching portion 35.
The radar device corresponds to the radar device 10 and
The fixed part corresponds to the fixed parts 23 and 33,
The position control means corresponds to the rib 29,
The board mounting part and elastic locking part correspond to snap fit 26,
The pivot and position holder correspond to the position holder 50,
The terminal part corresponds to the terminal part 42,
The terminal cover part corresponds to the terminal cover part 22 and
The insertion posture portion corresponds to the inclined convex portion 52, and corresponds to the inclined convex portion 52.
The orthogonal direction corresponds to the vertical direction Z,
The insertion direction corresponds to the depth direction H,
The front and back directions correspond to the vertical direction z,
Although the in-plane direction corresponds to the depth direction H and the width direction W, the present invention is not limited to the configuration of the above-described embodiment, and many embodiments can be obtained.
For example, in the position holder 50 described above, the block main body 51 is provided with a plurality of inclined convex portions 52, but the block main body 51 itself may be configured in a substantially parallel quadrilateral shape in a side view without providing the inclined convex portions 52.

Further, in the above description, in the upper case 20, the snap fit 26 is provided on the rear side Hb in the depth direction facing the terminal cover portion 22 on the front side Hf in the depth direction, but the upper case has a rectangular shape in a plan view. In 20, a snap fit 26 may be provided on a long side portion along the depth direction H to lock the antenna substrate 40.

10 ... Radar device 10a ... Housing 20 ... Upper case 22 ... Terminal cover part 23 ... Fixed part 25 ... Sandwiched part 26 ... Snap fit 29 ... Rib 30 ... Lower case 33 ... Fixed part 35 ... Sandwiched part 40 ... Antenna board 42 ... Terminal Part 50 ... Position holder 52 ... Inclined convex portion 412 ... Notched concave portion H ... Depth direction z ... Vertical direction

Claims (3)

An antenna board with an antenna part that transmits and receives radio waves on the surface,
An upper case that covers the antenna board at a predetermined distance from the surface of the antenna board, and an upper case.
It is composed of a lower case that covers the back surface side of the antenna board at predetermined intervals.
The upper case and the lower case form a housing, and the upper case and the lower case form a housing.
The lower case is made of a conductive member having conductivity.
In the upper case and the lower case, at locations facing the front and back directions, which are the thickness directions of the antenna substrate .
A radar device provided with a sandwiching portion for sandwiching and fixing the substrate edge portion of the antenna board in the front-back direction. The radar device according to claim 1, wherein the upper case is provided with a position regulating means for regulating the position of the antenna substrate with respect to the upper case in the in-plane direction. The radar device according to claim 1 or 2 , wherein the fixing portion for fixing the upper case and the lower case in the front-back direction is provided outside the radio wave influence range of the antenna portion on the antenna board.

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