JP4916013B2 - Antenna cable drawer structure - Google Patents

Description

  The present invention relates to an antenna cable drawing structure in which the antenna gain does not change even if the cable drawing direction is changed.

Japanese Patent Application Laid-Open No. 2001-68912 discloses a technique for pulling out a cable of a planar antenna in which the cable can be pulled out in the horizontal direction and the cable can be pulled down and the pulling direction can be selected. When the flat antenna is magnetically attracted to the vehicle body at the center of the automobile roof panel or the like, it is convenient to arrange the flat antenna along the roof panel if the cable is pulled out in a substantially horizontal direction. When it is attached to the edge of the roof panel at the top of the door, it is convenient for the cable to be drawn into the vehicle through the gap at the top of the window if the cable is drawn downward. Therefore, the cable drawing direction can be switched according to the place where the planar antenna is installed.
JP 2001-68912 A

  In recent years, a composite antenna device in which a planar antenna as a GPS antenna and a planar antenna as an ETC antenna are accommodated in a single housing has become widespread. The GPS antenna is arranged so that the directivity direction with the maximum gain is the zenith direction, while the ETC antenna is arranged so that the directivity direction with the maximum gain is tilted slightly forward from the zenith direction. Is done. Therefore, the posture of installing such a composite antenna device is restricted. For example, if it is installed on the front dash of an automobile, the maximum gain direction of the ETC antenna must be disposed obliquely upward in front of the automobile. Here, there are cases where different directions are required for the direction of drawing out the cable drawn from the composite antenna device, depending on the installed vehicle.

  It is not economical to prepare antenna devices with different cable pulling directions in response to the requirements of different cable pulling directions. If the drawn cable is further bent in the required direction, there is a serious problem that the antenna gain varies and the appearance is not excellent. The variation in antenna gain caused by further bending the cable in the required direction will be described with reference to FIGS. FIG. 10 is a plan view when the cable drawn from the planar antenna is further bent and led in the required direction. FIG. 11 is a diagram illustrating gain characteristics depending on the direction in which the cable is led out by the planar antenna of FIG. In FIG. 10, a GPS antenna 12, which is a planar antenna, has a patch antenna 12b mounted on a GPS board 12, and a ground electrode (not shown) is disposed on almost the entire lower surface of the GPS board 12a. The GPS cable 16 having one end connected to the GPS antenna 12 is drawn out in a plane substantially parallel to the ground electrode, and is led out by being further bent at a position relatively close to the outside of the edge of the GPS board 12a. Are different. In FIG. 10, the GPS cable 16 a is derived without being bent so as to be orthogonal to the edge of the GPS board 12 a, and the GPS cable 16 b is parallel to the edge of the GPS board 12. When the GPS cable 16c is led to be parallel to the edge of the GPS board 12a and bent to the opposite side of the GPS cable 16b. It is. The gain differs depending on the direction in which these GPS cables 16 are led out. As shown in FIG. 11, the measured gain in the zenith direction is 2.73 dBi for the GPS cable 16a, 3.50 dBi for the GPS cable 16b, and 4.26 dBi for the GPS cable 16c. Met. As a result, a variation in gain of 1.53 dBi was recognized in the GPS antenna 12 due to the difference in the direction in which the GPS cable 16 was led. This variation in gain can be understood because the electromagnetic wave radiated from the GPS cable 16 affects the patch antenna 12b, and the degree of influence varies depending on the direction in which the GPS cable 16 leads.

  By the way, although the above-mentioned GPS antenna 12 has an average gain of about 3.5 dBi, the specification value of an automobile manufacturer or the like for the GPS antenna 12 is about 2.0 dBi or more. Therefore, in the above-described conventional technology, there is a possibility that the gain obtained may be lower than the specification value due to the gain being varied due to the change in the pulling direction of the GPS cable 16. For this reason, the GPS antenna 12 with little variation in gain is required even if the direction of the GPS cable 16 is changed.

  The present invention has been made in view of the circumstances of the prior art as described above, and an object of the present invention is to provide an antenna cable drawing structure with little variation in gain even when the direction of drawing the cable from the antenna is changed.

In order to achieve such an object, the cable lead-out structure of the antenna of the present invention comprises an antenna having a ground electrode on the lower side and a cable having one end connected to the antenna, and the cable is placed under the ground electrode. The cable is bent in the lead- out direction within a range that is invisible to the ground electrode when viewed from above, and the cable is changed in a direction substantially parallel to the ground electrode by changing the bend in the lead- out direction. It is configured so that it can be pulled out in any one direction.

  Then, a base member is provided below the ground electrode, a plurality of guide grooves are provided on the lower surface of the base member to guide the cable in the pull-out direction, and the cable is inserted into the guide groove that guides the cable in either direction. The cable drawing direction may be set.

  In addition, a bracket may be provided on the lower side of the base member so that the cable does not come out of the guide groove.

  Further, the antenna may be a GPS antenna.

In the cable lead-out structure of the antenna according to claim 1, the cable is bent in the pull-out direction in a range below the ground electrode and invisible to the ground electrode when viewed from above, and the bending in the pull-out direction is performed. In other words, since it is drawn out in a plane substantially parallel to the ground electrode, the electromagnetic wave radiated from the cable at the portion where the bending is different due to the difference in the drawing direction is shielded by the ground electrode , and the degree of influence on the antenna is small. Therefore, variation in antenna gain due to a difference in the cable drawing direction is reduced.

  In the cable lead-out structure of the antenna according to claim 2, a guide groove for guiding the cable in a plurality of directions is provided in a base member provided below the ground electrode, and the cable is inserted into one of the guide grooves. Since the drawing direction is set, the bent shape of the cable is constant when it is drawn in any direction, and the drawing direction is also constant without forming an extremely sharp portion.

  In the antenna cable lead-out structure according to claim 3, since the bracket is provided on the lower side of the base member so that the cable does not come out of the guide groove, the cable can be securely held with a simple structure. .

  An embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a plan view when a cable is pulled out in a required direction from a GPS antenna to which an embodiment of an antenna cable pulling structure according to the present invention is applied. FIG. 2 is a diagram illustrating a gain characteristic depending on a difference in a cable drawing direction by the GPS antenna of FIG. 3A and 3B show an antenna device to which an embodiment of the antenna cable lead-out structure of the present invention is applied. FIG. 3A is a plan view, and FIG. 3B is a cross-sectional view taken along the line A-A in FIG. is there. 4 is an external perspective view of the antenna device shown in FIG. FIG. 5 is an exploded perspective view of the antenna device shown in FIG. 3 as viewed obliquely from the lower side. 6 is an external perspective view of a base member constituting the antenna device of FIG. 3, (a) is a perspective view of the bottom surface, and (b) is a perspective view of the top surface. FIG. 7 is a view showing the lower surface of the base member in a state where the cable is drawn out and wired to the rear of the antenna device. FIG. 8 is a view showing the lower surface of the base member in a state in which the cable is drawn out and wired to one side of the antenna device. FIG. 9 is a diagram showing the lower surface of the base member in a state where the cable is drawn out and wired to the other side of the antenna device.

First, with reference to FIG. 1 and FIG. 2, a GPS antenna to which an embodiment of the antenna cable lead-out structure of the present invention is applied will be described. In FIG. 1, a GPS antenna 12 which is a planar antenna has a patch antenna 12b mounted on a GPS board 12a, and a ground electrode (not shown) is disposed on almost the entire lower surface of the GPS board 12a. This is the same as the prior art shown in FIG. However, the GPS cable 16 having one end connected to the GPS antenna 12 is below the ground electrode provided on the lower side of the GPS board 12a and is not visible by the GPS board 12a (that is, the ground electrode) when viewed from the upper side. In addition, it is configured to bend in the lead- out direction within a plane substantially parallel to the ground electrode, and to set one of a plurality of lead-out directions by changing the bend in the lead-out direction. In FIG. 1, the GPS cable 16a is drawn without being bent so as to be orthogonal to the edge of the GPS board 12a, and the GPS cable 16b is parallel to the edge of the GPS board 12a. When the GPS cable 16c is pulled out so as to be parallel to the edge of the GPS board 12a and to the opposite side of the GPS cable 16b. It is. Due to the difference in bending of the GPS cable 16 in the pull-out direction, the gain is 3.38 dBi in the zenith direction as shown in FIG. In 16b, it was 3.70 dBi, and in GPS cable 16c, it was 3.26 dBi. As a result, the variation in gain due to the difference in the drawing direction of the GPS cable 16 was 0.44 dBi. The variation in the gain is significantly smaller than that of the conventional structure shown in FIG. 10, and the gain is about 2.0 dBi or more, which is a specification value of an automobile manufacturer or the like with respect to the GPS antenna 12. Therefore, in the present invention, even if the pulling direction of the GPS cable 16 is changed, there is no possibility that the gain falls below the specification value.

  Next, an antenna apparatus to which an embodiment of the antenna cable lead-out structure of the present invention is applied will be described. This antenna device is housed and disposed in a case 10 made of a resin material, which also functions as a radome, with a GPS antenna 12 and an ETC antenna 14 arranged side by side from below. The GPS antenna 12 has a patch antenna 12b mounted on the upper surface of the GPS substrate 12a, a ground electrode is disposed almost on the entire lower surface of the GPS substrate 12a, and a low noise amplifier circuit (not shown) is provided. A shield cover 12c is provided to cover the noise amplification circuit. One end of a GPS cable 16 is appropriately electrically connected and fixed to the GPS board 12a by soldering or the like. In addition, the ETC antenna 14 is configured such that a planar antenna element 14b is arranged in parallel with a space above the ETC substrate 14a. One end of an ETC cable 18 is appropriately electrically connected and fixed to the ETC board 14a by soldering or the like. A base member 20 made of a resin material is disposed below the GPS antenna 12 and the ETC antenna 14, and a GPS cable 16 and an ETC cable are provided by guide grooves 20a and 20b provided on the lower surface of the base member 20. 18 is guided and wired appropriately. Further, a bracket 22 made of a steel plate is provided in contact with the lower surface of the base member 20, and the disconnection of the GPS cable 16 and the ETC cable 18 inserted into the guide grooves 20a and 20b is restricted.

  Here, with respect to the antenna device, the GPS antenna 12 is disposed so that the vertical direction is in the directing direction, and the ETC antenna 14 is disposed so that the diagonally upward direction is in the directing direction. Same as technology. Therefore, in the antenna device in which such a plurality of antennas are arranged, as described above, if the antenna device is arranged on the dashboard of the automobile, the ETC antenna 14 must be arranged in front of the automobile. In other words, the posture of disposing the antenna device is restricted. And the direction which pulls out the cable 16 for GPS and the cable 18 for ETC is not necessarily the back of the case 10 by the request of the automobile manufacturer. Therefore, in the present invention, as described later, the guide grooves 20a and 20b provided on the lower surface of the base member 20 allow the GPS cable 16 and the ETC cable 18 to be pulled out according to the demand of the automobile manufacturer. Can be arbitrarily selected as either one of the rear and both sides.

  One guide groove 20a provided on the lower surface of the base member 20 guides the wiring by inserting the GPS cable 16, and a portion on one end side where one end is connected to the GPS antenna 12 is inserted. It is formed by one groove, and is formed so as to be branched into three grooves from the middle and reach the rear and both sides of the case 10, respectively. The other guide groove 20b is for guiding the wiring by inserting the ETC cable 18, and a portion on one end side where one end is connected to the ETC antenna 14 is inserted as a single groove. It is formed so that it is branched into three grooves from the middle and reaches the rear and both sides of the case 10, respectively. The two guide grooves 20a and 20b are formed substantially in parallel at any of the portion formed by one and the portion branched into three.

  Furthermore, retaining portions 20c and 20c are respectively provided in portions formed by one groove of the guide grooves 20a and 20b. The retaining portions 20c and 20c are formed by locking protrusions provided so as to be opposed from both sides of the edge of the groove so that the opening sides of the guide grooves 20a and 20b are narrowed. The locking projection is provided with a tapered surface on the upper surface side so that the GPS cable 16 and the ETC cable 18 can be easily inserted into the guide grooves 20a and 20b, and the GPS cable 16 and the ETC cable on the inner side. A surface substantially orthogonal to the depth direction of the groove is provided so that 18 does not come out. Further, the two guide grooves 20a, 20b are provided with a plurality of holding portions 20d, 20d,. The sandwiching portions 20d and 20d are formed by rib-like protrusions provided in the depth direction of the groove so as to face both sides of the groove so that the width of the guide grooves 20a and 20b is narrow. The rib-shaped protrusions are set such that the GPS cable 16 and the ETC cable 18 are inserted into the guide grooves 20a, 20b by appropriately elastically deforming the cable covering.

  Although the base member 20 is mass-produced by resin molding, in order to eliminate molding defects due to resin sinks or the like, as shown in FIG. At the same time, desired mechanical strength is ensured by the reinforcing ribs and the like. Further, at the locations where the retaining portions 20c, 20c are formed, holes 20e, 20e are provided at the bottoms of the guide grooves 20a, 20b, and the shape is sufficiently considered for the removal of the molding die. Yes.

  Then, as shown in FIG. 7, the GPS cable 16 and the ETC cable 18 are inserted into the guide grooves 20 a and 20 b of the base member 20, and inserted into the grooves that are branched and reach the rear, thereby Pulled out. Further, as shown in FIG. 8, the GPS cable 16 and the ETC cable 18 are inserted into the guide grooves 20a and 20b of the base member 20 and inserted into the branched groove that reaches one side. 10 pulled out to one side. Then, as shown in FIG. 9, the GPS cable 16 and the ETC cable 18 are inserted into the guide grooves 20a and 20b of the base member 20 and then inserted into the groove that reaches the other branched side. 10 is pulled out to the other side. Needless to say, the case 10 is provided with cable insertion holes 10a, 10a,... Corresponding to the branching of the guide grooves 20a, 20b of the base member 20 to the rear and both sides. 7 to 9 are views seen from the lower side with the bracket 22 removed.

  In such a configuration, in the cable lead-out structure of the antenna according to the present invention, the GPS cable 16 and the ETC cable 18 are inserted into the branched groove of the guide grooves 20a and 20b. The drawing direction can be appropriately selected and set. Since the cable covers of the GPS cable 16 and the ETC cable 18 are elastically deformed and inserted into the guide grooves 20a, 20b by the holding portions 20d, 20d... Provided in the guide grooves 20a, 20b, the GPS A large frictional resistance force is generated with respect to the force of pulling the cable 16 and the ETC cable 18 in the length direction. In addition, since a plurality of the holding portions 20d, 20d,... Are provided at intervals, the force of pulling in the length direction is offset by the frictional resistance force of each of the holding portions 20d, 20d, ... The pulling force in the vertical direction does not act on the portions where the GPS cable 16 and the ETC cable 18 are connected to the GPS board 12a and the ETC board 14a, respectively. Further, the GPS cable 16 and the ETC cable 18 inserted into the guide grooves 20a and 20b are regulated by the retaining portions 20c and 20c, and pulled downward by the GPS cable 16 and the ETC cable 18. Even if force is applied, it cannot be easily removed.

  The antenna device described above is a composite antenna device in which the GPS antenna 12 and the ETC antenna 14 are accommodated in one case 10, but the antenna in which the GPS antenna 12 or the ETC antenna 14 is independently accommodated in the case 10 is used. It will be easily understood that the antenna cable lead-out structure of the present invention can be applied even in the apparatus. In this case, of course, one cable is pulled out. Further, the antenna is not limited to the GPS antenna 12 or the ETC antenna 14, and may be an antenna for other purposes. The cable drawing direction is not limited to the three directions on the rear side and both sides of the case 10, and may be appropriately formed in two or more directions within a plane parallel to the lower surface of the base member 20. Further, the cable insertion holes 10a, 10a,... Provided in the case 10 may be opened in advance so that the cables 16 and 18 can be inserted, but are initially closed with thin members and the like, A thin member or the like may be cut out in accordance with the drawing direction so that the cables 16 and 18 can be inserted.

It is a top view at the time of pulling out a cable in the required direction from the GPS antenna to which one embodiment of the cable pulling structure of the antenna of the present invention is applied. It is a figure which shows the gain characteristic by the difference in the pulling-out direction of the cable by the GPS antenna of FIG. The antenna apparatus with which one Example of the cable drawing structure of the antenna of this invention is applied is shown, (a) is a top view, (b) is an AA cross-sectional arrow view of (a). It is an external appearance perspective view of the antenna apparatus shown in FIG. It is the disassembled perspective view which looked at the antenna apparatus shown in FIG. 1 from the lower diagonal. It is an external appearance perspective view of the base member which comprises the antenna apparatus of FIG. 1, (a) is a perspective view of a lower surface, (b) is a perspective view of an upper surface. It is a figure which shows the lower surface of the base member of the state which pulled out and wired the cable to the back of the antenna apparatus. It is a figure which shows the lower surface of the base member of the state which pulled out and wired the cable to one side of the antenna apparatus. It is a figure which shows the lower surface of the base member of the state which pulled out and wired the cable to the other side of the antenna apparatus. It is a top view at the time of further bend | folding the cable pulled out from the planar antenna and guide | inducing in the requested | required direction. It is a figure which shows the gain characteristic by the direction which a cable guides with the planar antenna of FIG.

Explanation of symbols

10 Case 12 GPS antenna 12a GPS substrate 12b Patch antenna 14 ETC antenna 14a ETC substrate 14b Planar antenna element 16 GPS cable 18 ETC cable 20 Base member 20a, 20b Guide groove 22 Bracket

Claims (4)

An antenna having a ground electrode on the lower side and a cable having one end connected to the antenna, the cable being pulled out in a range below the ground electrode and invisible to the ground electrode when viewed from the upper side The cable can be pulled out in any one of a plurality of different directions within a plane substantially parallel to the ground electrode by changing the bending in the direction and bending in the pulling direction. Cable pullout structure for the antenna. 2. The antenna cable drawing structure according to claim 1, wherein a base member is provided below the ground electrode, a guide groove is provided on the lower surface of the base member to guide a plurality of drawing directions, A cable pulling structure for an antenna, wherein the cable pulling structure is configured to be inserted into the guide groove guided in a direction to set a pulling direction of the cable. 3. The antenna cable drawing structure according to claim 2, wherein a bracket is provided below the base member so that the cable does not come out of the guide groove. 2. The antenna cable lead-out structure according to claim 1, wherein the antenna is a GPS antenna.