This application is the U.S. National Phase under 35 U.S.C. §371 of International Application PCT/JP 2004/003133, filed on Mar. 10, 2004, which claims priority of Japanese Patent Application No. 2003-085516, which was filed on Mar. 26, 2003. The International Application was published under PCT Article 21(2) in a language other than English.
The present invention relates to a patch antenna capable of transmitting and receiving circularly polarized waves or linearly polarized waves.
A short range communication system called DSRC (Dedicated Short Range Communication) is known. DSRC is a wireless communication system for radio wave ranges of between several meters and several tens of meters used in ETC (Electronic Toll Collection Systems) and ITS (Intelligent Transport Systems). ETC is a system for paying tolls automatically which works by conducting communication between an antenna disposed on a tollgate and an in-vehicle device installed in a vehicle when an automobile passes through a toll booth on an expressway or the like. Using ETC eliminates the need to stop at toll booths, and hence the amount of time required for the automobile to pass through the tollgate is reduced greatly. As a result, traffic congestion in the vicinity of toll booths can be eased, and exhaust gas amounts can be reduced.
ITS is a transport system fusing a system for providing automobiles with intelligence such as a car navigation system, and a system for providing roads with intelligence such as a wide range traffic control system. Examples of a car navigation system include a system enabling collaboration with VICS (Vehicle Information and Communication Systems) When ITS is used in this way, information relating to minor roads gathered by the police and information relating to expressways gathered by the Metropolitan Expressway Public Corporation and the Japan Highway Public Corporation is edited and issued from the VICS center. Upon reception of this information, the car navigation system is able to search for a route which bypasses a traffic jam or the like, and display the route on its monitor.
Typically, a patch antenna is used as the antenna in DSRC and ETC. A constitutional example of a prior art patch antenna is shown in
In the prior art patch antenna 100 shown in
However, the required constitutional components of the patch antenna 100 shown in
It is therefore an object of the present invention to provide a patch antenna which is reasonably priced and easy to assemble.
To achieve this object, a patch antenna of the present invention is constituted by a planar antenna plate formed with a perturbation element, a planar ground plate disposed opposite the antenna plate with a predetermined gap therebetween, and a spacer having a predetermined permittivity disposed between the antenna plate and the ground plate. The antenna plate is formed with an attachment hole, and the ground plate is formed with an insertion hole. By having a first L-shaped holding portion, which is formed as a protrusion from one surface of the spacer, grip the periphery of the attachment hole, the antenna plate is fixed to the spacer, and by having a second L-shaped holding portion, which is formed as a protrusion from the other surface of the spacer, grip the periphery of the insertion hole, the ground plate is fixed to the spacer.
In the patch antenna of the present invention, a cable has a ground portion connected to the ground plate and a core wire for supplying electricity to the antenna plate. The core wire may be inserted into and held by an insertion hole of a holding piece formed integrally with the spacer.
Further, in the patch antenna of the present invention, the core wire of the cable fixed to the rear surface of the ground plate may be inserted into the insertion hole of the holding piece through an insertion hole formed in the ground plate, and an annular rib formed so as to protrude from the lower surface of the holding piece may be fitted into the insertion hole in the ground plate.
Further, in the patch antenna of the present invention, an assembly constituted by fixing together the antenna plate, spacer, and ground plate, each of which is formed with a through hole, may be stored in a storage space of a first case and a second case by fitting a protruding portion formed as a protrusion in the storage space of the first case through the through holes, and fitting the first case onto the second case, which comprises in the storage space thereof an annular protruding portion for receiving a tip end portion of the protruding portion.
Further, in the patch antenna of the present invention, the assembly may be aligned with the second case by fitting a bent piece, which is formed by bending an edge portion of the groundplate downward, into a fitting groove formed in the storage space of the second case.
According to the present invention, the patch antenna may be formed by having the first L-shaped holding portion, which is formed as a protrusion from one surface of the spacer, grip the periphery of the attachment hole formed in the antenna plate, and having the second L-shaped holding portion, which is formed as a protrusion from the other surface of the spacer, grip the periphery of the insertion hole formed in the ground plate. Thus the patch antenna can be assembled easily. Further, the antenna plate and ground plate can be formed by stamping metal plates made of brass or the like, and the spacer can be formed by molding a resin such as polyacetal, and hence the cost of the patch antenna can be reduced.
By inserting the annular rib formed so as to protrude from the lower surface of the holding piece into the insertion hole formed in the ground plate, the core wire of the cable can be prevented from contacting the ground plate even when heat generated during soldering of the core wire to the antenna plate melts the cable insulator.
Moreover, by fitting the protruding portion formed on the first case portion into the through hole formed in the patch antenna such that the first case portion is fitted onto the second case portion, the patch antenna can be aligned with and stored in the case. Here, the bent piece formed by bending the edge portions of the antenna plate downward is fitted into the fitting groove formed on the second case, and thus the patch antenna can also be aligned with the second case.
The constitution of a patch antenna according to an embodiment of the present invention is shown in
A patch antenna 1 of the present invention shown in these drawings is capable of transmitting and receiving circularly polarized waves. The patch antenna 1 comprises an antenna plate 12 and a ground plate 13 created by processing metal plates made of brass or the like, and a spacer 14 made of a synthetic resin such as polyacetal, which is disposed between the antenna plate 12 and ground plate 13 so that the antenna plate 12 and ground plate 13 face each other with a predetermined gap therebetween.
The antenna plate 12 is fixed to the upper surface of the spacer 14, and the ground plate 13 is fixed to the lower surface of the spacer 14. Thus the antenna plate 12, spacer 14, and ground plate 13 are assembled as an integral unit. A cable 15 is connected to a predetermined feeding position on the antenna plate 12. The cable 15 is a coaxial cable having a braid wire serving as a ground portion soldered to the rear surface of the ground plate 13, and a core wire inserted through the ground plate 13 and spacer 14 and soldered to the antenna plate 12. The assembly constituted by the antenna plate 12, spacer 14, and ground plate 13 is aligned with and stored in a two-part case comprising an upper case 10 and a lower case 11 in a manner to be described below. The upper case 10 and lower case 11 are fixed together by a fixing screw 16.
The assembly process of the patch antenna 1 according to this embodiment of the present invention is shown in
First, before describing the assembly process, the constitution of each component will be described in detail. The constitution of the antenna plate 12 is shown in detail in the front view of
The constitution of the ground plate 13 is shown in detail in
As shown in the drawings, the ground plate 13 comprises a ground plate main body 13a formed by stamping a metal plate made of brass or the like. Three sides of the ground plate main body 13a are bent downward to form elongated bent pieces 13b. A circular through hole 13c is formed in the substantial center of the ground plate main body 13a, and a pair of rectangular insertion holes 13d are formed on both sides of the through hole 13c. Second L-shaped holding portions 14e of the spacer 14, to be described below, are fitted through the insertion holes 13d. A further insertion hole 13e for inserting the insulated core wire of the cable 15 is formed in a position corresponding to the connection hole 12d in the feeding position of the antenna plate 12, and a pair of stamped rectangular binding pieces 13f, which are soldered to and bind the braid wire of the cable 15, are formed on the rear surface of the ground plate 13.
The constitution of the spacer 14 is shown in detail in
As shown in the drawings, the spacer 14 is constituted by a spacer main body 14a and an annular feeder line holding piece 14d formed as an extension from the spacer main body 14a. A circular through hole 14c is formed in the substantial center of the spacer main body 14a, a pair of first L-shaped holding portions 14b are formed as protrusions from the upper surface of the spacer main body 14a, and a pair of second L-shaped holding portions 14e are formed as protrusions from the lower surface of the spacer main body 14a. The tip ends of the first L-shaped holding portions 14b and second L-shaped holding portions 14e are formed so as to face opposite directions to each other. Further, the upper portions of the first L-shaped holding portions 14b and second L-shaped holding portions 14e, which are substantially parallel to the spacer main body 14a, face the spacer main body 14a with a slight gap therebetween, the gap becoming gradually narrower toward the tip end. The antenna plate 12 or ground plate 13 is inserted into the gap between the upper portions of the first L-shaped holding portions 14b and second L-shaped holding portions 14e and the spacer main body 14a, and thus gripped thereby and held. Since the gap becomes gradually narrower toward the tip end, the antenna plate 12 and ground plate 13 can be fixed securely to the spacer 14 by the first L-shaped holding portions 14b and second L-shaped holding portions 14e.
The annular feeder line holding piece 14d extending from the spacer main body 14a is formed with an insertion hole 14f and an annular rib 14g which protrudes downward from the periphery of the insertion hole 14f. The core wire of the cable 15, wrapped in an insulator, is inserted into the insertion hole 14f, and the annular rib 14g is fitted into the insertion hole 13e formed in the ground plate 13. Note that the spacer 14 is created by molding a resin having a predetermined permittivity such as polyacetal.
Returning to
Next, with the antenna plate 12 fixed to the spacer 14, the pair of second L-shaped holding portions 14e are inserted into the pair of insertion holes 13d formed in the ground plate 13 such that the upper portions of the second L-shaped holding portions 14e protrude from the insertion holes 13d. The ground plate 13 is then slid downward so that the peripheries of the insertion holes 13d are gripped between the upper portions of the protruding second L-shaped holding portions 14e and the spacer main body 14a. As a result, the lower portions of the insertion holes 13d in the ground plate 13 are gripped between the upper portions of the second L-shaped holding portions 14e and the spacer main body 14a such that the ground plate 13 is fixed to the spacer 14. Further, the annular rib 14g formed on the feeder line holding piece 14d is fitted into the insertion hole 13e.
Thus the antenna plate 12 is fixed to the front surface of the spacer 14, and the ground plate 13 is fixed to the rear surface of the spacer 14. In this state, the cable 15 is disposed on the rear surface of the ground plate 13, and an insulator 15b covering the core wire 15a is inserted through the insertion hole 13e and then inserted through the insertion hole 14f in the feeder line holding piece 14d such that the core wire 15a protruding from the tip end of the insulator 15b is inserted into the connection hole 12d formed on the antenna plate 12. The core wire 15a inserted into the connection hole 12d is then soldered so that the core wire 15a is connected to the antenna plate 12. The braid wire 15c of the cable 15 is bound to the pair of binding pieces 13f by caulking, and then soldered. Thus the assembly is assembled, and the cable 15 leads out from the assembly.
A front view of the constitution of the assembly 2 is shown in
As shown in these drawings, a connection terminal 17 attached to a communication device is provided on the tip end of the cable 15 leading out from the assembly 2. Also, the positions of the through hole 12b formed in the antenna plate 12, the through hole 14c formed in the spacer 14, and the through hole 13c formed in the groundplate 13 are in substantial alignment within the assembly 2. Since the insulating annular rib 14g is fitted into the insertion hole 13e as shown in
This assembly 2 is stored in a case comprising the upper case 10 and lower case 11. The constitution of the upper case 10 and lower case 11 will now be described.
The constitution of the upper case 10 is shown in detail in
As shown in these drawings, a side wall portion 10b of a predetermined height is formed on the four sides of a rectangular upper case main body 10a of the upper case 10, and a storage space is formed in the interior thereof. A tubular protruding portion 10c that is longer than the side wall portion 10b is formed so as to stand in the substantial center of the storage space, and a pair of rectangular recessed portions 10e is formed on both sides thereof. Further, a pair of protrusions 10g having a small diameter are formed in opposing corners, and a cable holding portion 10f in the form of a semicircular groove, into which the cable 15 is introduced, is formed as a protrusion from one side of the side wall portion 10b.
A screw portion 10d is formed on the inner peripheral surface of the tubular protruding portion 10c. A fixing screw inserted through the lower case 11 is screwed into the screw portion 10d to integrate the upper case 10 and lower case 11. When storing the assembly 2 in the upper case 10, the assembly 2 is aligned with the upper case 10 by inserting the protruding portion 10c through the through hole 12b, through hole 14c, and through hole 13c in the assembly 2. The upper portions of the first L-shaped holding portions 14b protruding from the antenna plate 12 of the assembly 2 can be stored inside the recessed portions 10e formed on the inner surface of the upper case 10.
The constitution of the lower case 11 is shown in detail in
As shown in the drawings, a side wall portion 11b of a predetermined height is formed on the four sides of a rectangular lower case main body 11a of the lower case 11, and a storage space is formed in the interior thereof. A short annular protruding portion 11c is formed in the substantial center of the storage space, and a cut-away portion 11f, the lower portion of which takes the form of a semicircular groove into which the cable 15 is introduced, is formed on one side of the side wall portion 11b. The cable holding portion 10f formed in the upper case 10 fits into a rectangular groove in the upper portion of the cut-away portion 11f. A cable holding groove 11i for accommodating the introduced cable 15 is formed from the cut-away portion 11f to the annular protruding portion 11c.
A pair of protrusions 11g having a small diameter is formed in opposing corners. These protrusions 11g are designed to abut against the protrusions 10g formed on the upper case 10 when the upper case 10 is fitted onto the lower case 11. Further, a through hole 11e is formed in the substantial center of the annular protruding portion 11c, and an annular groove portion 11d is formed on the tip end thereof. This annular groove portion 11d is designed to receive the tip end of the protruding portion 10c of the upper case 10 when the upper case 10 is fitted onto the lower case 11. An annular recessed portion 11k is formed in the rear surface of the lower case main body 11a so as to surround the through hole 11e. This annular recessed portion 11k serves to accommodate the head of the fixing screw that is inserted into the through hole 11e. Further, an annular protruding portion 11j is formed so as to protrude from the inner peripheral surface of the side wall portion 11b surrounding the lower case main body 11a. The annular protruding portion 11j is fitted into the inner peripheral surface of the side wall portion 10b of the upper case 10 when the upper case 10 is fitted onto the lower case 11. Elongated fitting grooves 11h are formed around three sides of the inside of the annular protruding portion 11j. When storing the assembly 2 in the lower case 11, the assembly 2 is aligned with the lower case 11 by fitting the bent pieces 13b formed on three sides of the ground plate 13 into these three fitting grooves 11h.
Next, the process for storing the assembly 2 in the case comprising the upper case 10 and lower case 11 will be described with reference to
As shown in
Next, the upper case 10 is fitted onto the lower case 11 storing the assembly 2 as shown in
In the patch antenna 1 of the present invention described above, the antenna plate 12 is described as being rectangular, but the present invention is not limited thereto, and the antenna plate 12 may be circular. In this case, the antenna plate 12 may be constituted by a circular antenna element comprising perturbation elements to enable the transmission and reception of circularly polarized waves. Moreover, in the above description, the patch antenna 1 is designed to be capable of transmitting and receiving circularly polarized waves, but the present invention is not limited thereto, and the patch antenna 1 may be designed to be capable of transmitting and receiving linearly polarized waves by employing linearly polarized wave antenna elements as the antenna elements of the antenna plate 12.
In the present invention, as described above, a patch antenna may be formed by having first L-shaped holding portions formed as protrusions from one surface of a spacer grip the periphery of attachment holes formed in an antenna plate, and having second L-shaped holding portions formed as protrusions from the other surface of the spacer grip the periphery of insertion holes formed in a ground plate. Thus the patch antenna can be assembled easily. Further, the antenna plate and ground plate can be formed by stamping metal plates made of brass or the like, and the spacer can be formed by molding a resin such as polyacetal, and hence the cost of the patch antenna can be reduced.
By inserting an annular rib formed so as to protrude from the lower surface of a holding piece into an insertion hole formed in the ground plate, the core wire of a cable can be prevented from contacting the ground plate even when heat generated during soldering of the core wire to the antenna plate melts the cable insulator.
Moreover, by fitting a protruding portion formed on a first case portion into a through hole formed in the patch antenna such that the first case portion is fitted onto a second case portion, the patch antenna can be aligned with and stored in the case. Here, bent pieces formed by bending the edge portions of the antenna plate downward are fitted into fitting grooves formed on the second case, and thus the patch antenna can also be aligned with the second case.
Number | Date | Country | Kind |
---|---|---|---|
2003-085516 | Mar 2003 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2004/003133 | 3/10/2004 | WO | 00 | 11/19/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/086562 | 10/7/2004 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
6181279 | Van Hoozen | Jan 2001 | B1 |
6549166 | Bhattacharyya et al. | Apr 2003 | B2 |
Number | Date | Country |
---|---|---|
1 291 970 | Mar 2003 | EP |
62-62446 | Apr 1987 | JP |
09-167908 | Jun 1992 | JP |
05-167345 | Jul 1993 | JP |
06-41220 | May 1994 | JP |
06-48210 | Jun 1994 | JP |
07-147507 | Jun 1995 | JP |
07-202555 | Aug 1995 | JP |
04-69910 | Jun 1997 | JP |
10-276019 | Oct 1998 | JP |
2001-345629 | Dec 2001 | JP |
2002-368513 | Dec 2002 | JP |
2003-046323 | Feb 2003 | JP |
2003-060425 | Feb 2003 | JP |
Number | Date | Country | |
---|---|---|---|
20060071856 A1 | Apr 2006 | US |