JP6876391B2 - Antenna unit, door handle device including it, and manufacturing method thereof - Google Patents

Description

The present invention relates to an antenna unit, a door handle device including the antenna unit, and a method for manufacturing the same.

Some vehicles in recent years include an antenna unit that automatically unlocks or locks the door when the driver carries a portable device with a transmitting function and brings his or her hand close to or touches the door handle.

The antenna unit is located inside the door handle of the vehicle and includes a proximity sensor that detects when a person's hand approaches or comes into contact with the door handle. For example, Patent Document 1 discloses an antenna unit using a self-capacitance type (capacitance type) proximity sensor. Since the self-capacity method is adopted in this antenna unit, one electrode is used, and the approach of the human body is detected by the change in the capacitance of the electrode caused by the finger approaching the electrode.

Japanese Patent No. 5480112

In the antenna unit adopting the self-capacity method as disclosed in Patent Document 1, since the approach of the human body is detected by only one electrode, it may be erroneously detected. On the other hand, it is conceivable to adopt a mutual capacitance method for the antenna unit. In the mutual capacitance type antenna unit, two electrodes are used, and the approach of the human body is detected by the change in voltage induced by the finger approaching the two electrodes. The mutual capacitance method can generally detect the approach of the human body with higher accuracy than the self-capacity method, but even if such a mutual capacitance method is adopted, it may still be erroneously detected. Further, since the mutual capacitance method uses two electrodes, the antenna unit tends to be larger than the self-capacity method.

An object of the present invention is to provide a miniaturized antenna unit capable of detecting the approach or contact of a human body with high accuracy.

The antenna unit according to the first aspect of the present invention receives the circuit board on which the detection circuit is printed, the drive electrode electrically connected to the detection circuit, and the electric power line generated from the drive electrode. A proximity sensor having a detection electrode and an antenna for transmitting and receiving signals between a portable device owned by the user are provided. In the antenna, a winding conductor is formed in an insulating bobbin containing a core portion made of rod-shaped ferrite. There is wound, the drive electrode and the first detection electrode is formed on both flat, opposed to being located, and, across the antenna during the previous SL drive electrode and the first detection electrode Arranged , the bobbin has an antenna mounting hole, the circuit board has a board mounting hole, and the driving electrode and the first detection electrode have a protruding shape inserted into the antenna mounting hole of the bobbin. The antenna mounting piece and the protruding board mounting piece inserted into the board mounting hole of the circuit board are provided.

In this configuration, a mutual capacitance method is adopted as a proximity sensor for detecting the approach or contact of the human body with high accuracy. When the human body approaches the antenna unit, the number of lines of electric force generated between the drive electrode and the first detection electrode decreases, and the voltage induced in the first detection electrode decreases. By detecting this decrease in voltage, it is possible to detect the approach or contact of the human body with the antenna unit. Further, since the drive electrode and the first detection electrode are arranged so as to face each other with the antenna in between, the space is effectively used and the antenna unit is miniaturized. Further, the antenna and the circuit board can be easily positioned and fixed to the drive electrode and the first detection electrode. As a result, it is not necessary to separately provide the positioning structure and the fixed structure, so that the configuration can be simplified.

A second detection electrode that is mounted on the circuit board within a range in which the electric lines of force generated from the drive electrode can be received and has a length shorter than that of the first detection electrode may be further provided.

According to this configuration, one drive electrode is provided for each of the two detection electrodes. That is, the drive electrodes are shared. Therefore, since two capacitors can be configured with one drive electrode, the antenna unit can be miniaturized. However, if the two capacitors share the drive electrode, the detection ranges of the two capacitors may overlap. On the other hand, by making the length of the second detection electrode shorter than the length of the first detection electrode, the detection range of the second detection electrode is limited and the overlap of the detection ranges is prevented. Therefore, for example, the first detection electrode may be used to detect the opening operation of the vehicle door, and the second detection electrode may be used to detect the closing operation of the vehicle door. Therefore, it is possible to distinguish the user's intention to operate and detect the approach or contact of the human body with the antenna unit.

An elastic flat plate portion may be further provided in the intermediate portion between the drive electrode and the first detection electrode on which the antenna and the circuit board are not arranged.

According to this configuration, even when an external force is applied to the antenna unit, the elastic flat plate portion absorbs the load and bends, so that the load applied to the antenna and the proximity sensor is reduced, and damage to internal parts can be prevented. ..

In the door handle device of the second aspect of the present invention, the antenna unit according to claim 4 is incorporated in the door handle of the vehicle door, and the deformation of the door handle is bent when the user pulls the door handle. The elastic flat plate portion is arranged at a position to be a point.

According to this configuration, the elastic flat plate portion of the antenna unit absorbs the load on the antenna unit due to the deformation at the bending point of the door handle and bends, so that the load applied to the internal parts of the antenna unit 20 is small. These damages can be prevented. Further, when the antenna unit is built in the door handle, the antenna unit can be arranged in a curved shape along the shape of the door handle.

In the method for manufacturing an antenna unit according to a third aspect of the present invention, a drive electrode and a first detection electrode are connected by a bridge-shaped connecting portion to form a protruding antenna mounting piece and a substrate mounting piece. An antenna having a bobbin on which an antenna mounting hole is formed, a circuit board on which a detection circuit is printed and having a substrate mounting hole, a mold for injection molding, and a cutting device provided so as to protrude into the mold. Is prepared, the antenna mounting piece of the electrode pair is inserted into the antenna mounting hole of the antenna, the antenna is mounted in the electrode pair, and the substrate mounting of the electrode pair is made in the board mounting hole of the circuit board. Insert the piece, attach the circuit board to the electrode pair,
The electrode pair, the antenna, and the circuit board are positioned and arranged in the mold, and molten resin is injected into the mold to form a resin mold that covers at least the antenna and the circuit board. The electrode pair, the antenna, and the circuit board are integrated, and the connecting portion is cut by the cutting device.

According to this method, since the drive electrode and the first detection electrode are connected by the connecting portion, the electrode pair does not shift in position during assembly. Further, since the connecting portion is cut in the injection molding process, the drive electrode and the first detection electrode can be separated without increasing the number of steps.

According to the present invention, in the antenna unit, the mutual capacitance method can be adopted to detect the approach or contact of the human body with high accuracy, and the drive electrode and the first detection electrode are arranged so as to face each other with the antenna in between. The space can be effectively used and miniaturized.

FIG. 3 is a cross-sectional view of the door handle device according to the first embodiment of the present invention. The perspective view of the antenna unit which concerns on 1st Embodiment of this invention. An exploded perspective view of the antenna unit according to the first embodiment of the present invention. FIG. 2 is a cross-sectional view of the antenna unit of FIG. 2 before processing. The cross-sectional view of the antenna unit of FIG. 2 after processing. The schematic diagram for demonstrating the mutual capacitance type proximity sensor. The schematic diagram for demonstrating the mutual capacitance type proximity sensor. An exploded perspective view of the antenna unit according to the second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

(First Embodiment)
As shown in FIG. 1, the door handle (door handle device) 10 of the present embodiment is attached to a vehicle door (not shown). The antenna unit 20 is incorporated in the door handle 10.

First, the configuration of the door handle 10 will be described.

The door handle 10 is composed of a handle body 11 that is long in the vehicle front-rear direction (direction of the double-headed arrow A) and a handle cover 12 that covers the surface of the handle body 11. The handle cover 12 is fastened to the handle body 11 by a screw (not shown). A space S is provided between the handle main body 11 and the handle cover 12, and the antenna unit 20 is arranged in the space S. Here, both the handle body 11 and the handle cover 12 are made of resin.

The arm 13 and the operating portion 14 project from the front end and the rear end of the handle body 11 at substantially right angles, respectively, and a shaft hole 13A is formed at the tip of the arm 13 forming an L-shape in a plan view. A support shaft 15 provided on the vehicle body side is fitted in the shaft hole 13A. The handle body 11 can rotate together with the handle cover 12 in the direction of arrow B in FIG. 1 about the support shaft 15.

An engaging recess 14A is formed in the operating portion 14 projecting from the rear end of the handle body 11, and the handle lever 16 is engaged with the engaging recess 14A. The handle lever 16 is for operating a door lock device (not shown) incorporated in the vehicle body. When the handle body 11 is rotated around the support shaft 15 in the direction of arrow B in FIG. 1, the handle lever 16 also moves in the same direction as the operating portion 14 of the handle body 11 moves. As a result, the door lock device is activated to unlock the door.

Next, the configuration of the antenna unit 20 will be described.

Each component of the antenna unit 20 shown in FIG. 2 is integrated by a resin mold 21. The resin mold 21 has support convex portions 21A and 21B integrally on the inner surface side (handle body 11 side) and the outer surface side (handle cover 12 side) at both ends (front end portion and rear end portion) in the longitudinal direction. It is rushed. The antenna unit 20 is supported in the door handle 10 by abutting and sandwiching the support convex portions 21A and 21B with the handle body 11 and the handle cover 12, respectively (see FIG. 1). The antenna unit 20 is arranged so as not to come into contact with the inner surfaces of the handle body 11 and the handle cover 12 at the central portion in the longitudinal direction thereof.

As shown in FIG. 3, the antenna unit 20 includes a base plate 30, a lock electrode (second detection electrode) 22, an antenna 23, and a circuit board 24. After these parts are assembled, the antenna unit 20 is integrated by the resin mold 21 (see FIG. 2). The resin mold 21 is molded in a box shape and has a parallel bottom surface 21C and a top surface 21D, two parallel side surfaces 21E and 21F, a front surface 21G, and a rear surface 21H as outer surfaces.

As shown in FIG. 3, the base plate 30 is formed by press-molding a metal plate, and has a circuit board accommodating portion 31 for arranging the circuit board 24 and an antenna accommodating portion 32 for arranging the antenna 23. , The elastic flat plate portion 33 for connecting the circuit board accommodating portion 31 and the antenna accommodating portion 32 is provided.

The circuit board accommodating portion 31 includes a flat plate-shaped bottom surface portion 34A in which the circuit board 24 is arranged in parallel, and two flat plate-shaped electrodes 35A formed by being vertically bent so that both sides of the bottom surface portion 34A face each other. , 36A and. The two electrodes 35A and 36A are arranged in parallel with each other, one forming a part of the driving electrode 35 and the other forming a part of the unlock electrode (first detection electrode) 36. Further, the bottom surface portion 34A and the elastic flat plate portion 33 are provided with an opening 31A extending in the longitudinal direction at the center thereof. A bridge-shaped first connecting portion 37A and a second connecting portion 37B are formed at both ends of the opening 31A in the longitudinal direction. The second connecting portion 37B is provided on the elastic flat plate portion 33. In other words, the two electrodes 35A and 36A are not connected by the bottom surface portion 34A and the elastic flat plate portion 33, but are connected by the bridge-shaped first connecting portion 37A and the second connecting portion 37B. Further, the circuit board accommodating portion 31 includes four substrate mounting pieces 38 formed by vertically bending a part of the bottom surface portion 34A. The four substrate mounting pieces 38 are formed in parallel with the two electrodes 35A and 36A.

The antenna accommodating portion 32 includes a flat plate-shaped bottom surface portion 34B on which the antenna 23 is arranged, and two flat plate-shaped electrodes 35B and 36B formed by being vertically bent so that both sides of the bottom surface portion 34B face each other. Have. The two electrodes 35B and 36B are arranged in parallel with each other, one forming a part of the driving electrode 35 and the other forming a part of the unlock electrode (first detection electrode) 36. The bottom surface portion 34B is provided with an opening 32A extending in the longitudinal direction at the center thereof. A bridge-shaped second connecting portion 37B and a third connecting portion 37C are formed at both ends of the opening 32A in the longitudinal direction. In other words, the two electrodes 35B and 36B are not connected by the bottom surface portion 34B and the elastic flat plate portion 33, but are connected by the bridge-shaped second connecting portion 37B and the third connecting portion 37C. Further, the antenna accommodating portion 32 includes four antenna mounting pieces 39 formed by partially bending the bottom surface portion 34B in the vertical direction, and the four antenna mounting pieces 39 are parallel to the two electrodes 35B and 36B. It is formed. Further, a cable support in which four notches 40A for supporting the input / output cables 23A and 24A of the antenna 23 and the circuit board 24 are formed at the end of the antenna accommodating portion 32 opposite to the circuit board accommodating portion 31. A unit 40 is provided.

The elastic flat plate portion 33 is a flat plate-shaped portion provided between the circuit board accommodating portion 31 and the antenna accommodating portion 32. The elastic flat plate portion 33 is formed by extending the bottom surface portion 34A and the bottom surface portion 34B, respectively, and connecting the extended bottom surface portions 34A and the bottom surface portion 34B. As described above, the elastic flat plate portion 33 is formed with a bridge-shaped second connecting portion 37B. The second connecting portion 37B connects the drive electrode 35 and the unlock electrode 36 together with the first connecting portion 37A and the third connecting portion 37C.

The drive electrode 35 is configured by integrating the two electrodes 35A and 35B into one electrode, and the unlock electrode 36 is configured by integrating the two electrodes 36A and 36B into one electrode. In the state before assembly shown in FIG. 3, the drive electrode 35 and the unlock electrode 36 are connected by the first to third connecting portions 37A to 37C. As will be described later, the driving electrode 35 and the unlocking electrode 36 are separated by cutting the first to third connecting portions 37A to 37C, and the driving electrode 35 and the unlocking electrode 36 form a capacitor 25. In the capacitor 25, the unlock electrode 36 receives the electric lines of force generated from the drive electrode 35. The capacitor 25, together with the circuit board 24, functions as a proximity sensor for detecting that the user approaches or touches the door handle 10 when unlocking the door.

The lock electrode 22 is formed by press-molding a metal plate to a length shorter than that of the unlock electrode 36, and is formed by vertically bending a plate main body 22A and a part of the plate main body 22A. It has a plate mounting piece 22B. The lock electrode 22 is provided corresponding to the drive electrode 35, and the capacitor 26 is composed of the lock electrode 22 and the drive electrode 35. In the capacitor 26, the lock electrode 22 receives the electric lines of force generated from the drive electrode 35. The capacitor 26 functions as a proximity sensor for detecting that the user approaches or touches the door handle 10 when the door is locked together with the circuit board 24.

The antenna 23 is for transmitting and receiving electromagnetic waves in order to communicate with a user's portable device (not shown). The antenna 23 includes an insulating bobbin 23B accommodating a core portion (not shown) made of rod-shaped ferrite, a winding conductor 23C wound around the bobbin 23B, and two input / output cables 23A extending from the bobbin 23B. And. Four antenna mounting holes 23D are formed in the bobbin 23B. The four antenna mounting holes 23D are formed corresponding to the antenna mounting piece 39, and the antenna mounting piece 39 can be inserted. The antenna 23 has a size that can be arranged in the antenna accommodating portion 32 of the base plate 30.

The circuit board 24 is electrically connected to two capacitors 25 and 26, and a detection circuit for detecting and outputting voltage changes induced by these capacitors is printed. The circuit board 24 has a quadrangular plate shape and is of a size that can be arranged in the circuit board accommodating portion 31 of the base plate 30. The circuit board 24 corresponds to three sensor mounting holes 24B and one end notch 24C provided corresponding to the four plate mounting pieces 22B of the lock electrode 22, and four antenna mounting pieces 39 of the base plate 30. It has four board mounting holes 24D provided in the above. Further, two input / output cables 24A are connected to the circuit board 24.

The procedure for assembling the antenna unit 20 will be described with reference to FIG.

First, the lock electrode 22 is assembled to the circuit board 24 to form the first assembly U1 (22, 24). Specifically, the plate mounting piece 22B of the lock electrode 22 is inserted into the sensor mounting hole 24B and the notch 24C of the circuit board 24, and these are electrically connected and fixed by soldering.

Second, the antenna 23 is assembled to the antenna accommodating portion 32 of the base plate 30 to form the second assembly U2 (23, 30). Specifically, the antenna mounting piece 39 of the antenna accommodating portion 32 is press-fitted into the antenna mounting hole 23D of the antenna 23, and the antenna 23 is assembled to the antenna accommodating portion 32 of the base plate 30. In the state of the second assembly U2 in which the antenna 23 is assembled to the antenna accommodating portion 32, the two input / output cables 23A of the antenna 23 are arranged and supported in the notch 40A of the cable support portion 40 of the base plate 30. ..

Thirdly, the first assembly U1 is assembled to the second assembly U2 to form the third assembly U3 (22, 23, 24, 30). Specifically, the antenna mounting piece 39 formed in the circuit board accommodating portion 31 of the base plate 30 of the second assembly U2 is inserted into the board mounting hole 24D formed in the circuit board 24 of the first assembly U1, and the first Assemble the assembly U1 to the second assembly U2. In the state where the first assembly U1 is assembled to the second assembly U2, the two input / output cables 24A of the circuit board 24 extend through both sides of the antenna 23, respectively, and the notch of the cable support portion 40 of the base plate 30 is cut out. It is arranged and supported in the portion 40A. In the state of the third assembly U3, the lock electrode 22 is mounted on the circuit board 24 within a range in which the electric lines of force generated from the drive electrode 35 can be received.

Fourth, the third assembly U3 is arranged in a mold (not shown) and integrated by injection molding. After injection molding, as shown in FIG. 2, the antenna unit 20 integrated by the resin mold 21 is formed. In the antenna unit 20 formed in this way, the drive electrode 35, the lock electrode 22, and the unlock electrode 36 are exposed from the surface of the resin mold 21. In this integrated state, the circuit board 24 (see FIG. 3) is arranged parallel to the bottom surface 21C and the top surface 21D of the resin mold 21, and the drive electrode 35 and the unlock electrode 36 are the antenna 23 and the circuit. It is arranged in parallel with the two side surfaces 21E and 21F of the resin mold 21 on both sides of the substrate 24.

As shown in FIG. 4A, when the first connecting portion 37A is sandwiched and fixed by the mold during normal injection molding, the resin mold 21 has a hole portion leading to the first connecting portion 37A. 21I is formed. However, in the present embodiment, as shown in FIG. 4B, at the same time as the resin is injected during injection molding, a cutting device (not shown) protrudes into the mold to cut the first connecting portion 37A. Further, the second and third connecting portions 37B and 37C (see FIG. 3) are also cut in the same manner. As a result, the drive electrode 35 and the unlock electrode 36 of the base plate 30 are completely separated, and two electrodes are formed. In this state, since the two electrodes (drive electrode 35 and unlock electrode 36) are fixed by the antenna 23 and the circuit board 24, the positions do not shift. Further, the holes leading to the first to third connecting portions 37A to 37C are filled with the resin mold 21 by moving the cutting device after cutting the first to third connecting portions 37A to 37C. However, it is not essential to fill those holes with the resin mold 21, and the cut first to third connecting portions 37A to 37C may be exposed.

In this way, since the drive electrode 35 and the unlock electrode 36 are connected by the first to third connecting portions 37A to 37C, the electrode pairs 35 and 36 do not shift in position during assembly. Further, since the first to third connecting portions 37A to 37C are cut in the injection molding process, the drive electrode 35 and the unlock electrode 36 can be separated without increasing the number of steps.

The antenna unit 20 manufactured as described above is housed in the space S defined by the handle body 11 and the handle cover 12, and the door handle 10 of the present embodiment is formed (see FIG. 1). At this time, the circuit board 24 and the antenna 23 are arranged in parallel with the bottom surface 21C and the top surface 21D of the resin mold 21, and are arranged in a row in the longitudinal direction of the door handle 10. The door handle 10 has a position P that is a bending point of deformation when the user pulls the door handle 10 to open the door. In this embodiment, the elastic flat plate portion 33 is arranged at the position P (see FIG. 1).

The operation and effect of the antenna unit 20 and the door handle 10 of the present embodiment derived from the above configuration will be described.

In the configuration of the present embodiment, a mutual capacitance method is adopted as a proximity sensor for detecting the approach or contact of a human hand. As shown in FIGS. 5A and 5B, when the finger 50 of a human hand approaches the capacitor 25 (26) in the antenna unit 20, it occurs between the drive electrode 35 and the detection electrode 36 (22) of the capacitor 25 (26). The number of lines of electric force to be generated decreases, and the voltage induced in the detection electrode 36 (22) decreases. In FIGS. 5A and 5B, when a voltage of 3 V is input to the drive electrode 35, the voltage induced in the detection electrode 36 (22) is 50 mV when the fingers 50 are not close to each other (see FIG. 5A). When the finger 50 is approaching, the voltage is reduced to 30 mV (see FIG. 5B). By detecting this voltage change, it is possible to detect the approach or contact of the human body with the antenna unit 20.

Further, since the drive electrode 35 and the unlock electrode 36 are arranged so as to face each other with the antenna 23 interposed therebetween, the space is effectively used and the antenna unit 20 is miniaturized.

Further, according to the structure of assembling the antenna 23 and the circuit board 24 to the base plate 30, the antenna 23 and the circuit board 24 can be easily positioned and fixed to the drive electrode 35 and the unlock electrode 36. As a result, it is not necessary to separately provide the positioning structure and the fixed structure, so that the configuration is simplified.

Further, according to the above configuration, one drive electrode 35 is provided for each of the two detection electrodes 22 and 36. That is, the drive electrode 35 is shared. Therefore, since two capacitors 25 and 26 can be configured by one drive electrode 35, the antenna unit 20 can be miniaturized. However, if the two capacitors 25 and 26 share the drive electrode 35, the detection ranges of the two capacitors 25 and 26 may overlap. On the other hand, by making the length of the lock electrode 22 shorter than the length of the unlock electrode 36, the detection range of the lock electrode 22 may be limited and the overlap of the detection ranges may be prevented. Therefore, it is possible to distinguish the user's intention to operate and detect the approach or contact of the human body with the antenna unit 20.

Further, since the elastic flat plate portion 33 is arranged at the position P which is the bending point of the deformation of the door handle 10 (see FIG. 1), the elastic flat plate portion 33 bears the load even when an external force is applied to the antenna unit 20. Since it absorbs and bends, the load applied to the internal parts of the antenna unit 20 is reduced, and damage to the internal parts can be prevented.

(Second Embodiment)
The exploded view of the antenna unit 20 of the second embodiment shown in FIG. 6 is the same as the configuration of the first embodiment of FIG. 3 except for the configuration related to the base plate 30. Therefore, the same parts as those shown in FIG. 3 are designated by the same reference numerals and the description thereof will be omitted.

In the present embodiment, unlike the first embodiment, the base plate 30 has a bottom surface portion 34A (see FIG. 3) of the circuit board accommodating portion 31 and a bottom surface portion 34B (see FIG. 3) of the antenna accommodating portion 32. Absent. Further, the aspect of the antenna mounting piece 39 in the circuit board accommodating portion 31 is different from that of the first embodiment. Specifically, in the present embodiment, the antenna mounting piece 39 is formed by partially bending the drive electrode 35 and the unlock electrode 36 at four points. Therefore, in the first embodiment, the circuit board 24 is assembled to the circuit board accommodating portion 31 from above in FIG. 3, but in the present embodiment, the circuit board 24 is assembled to the circuit board accommodating portion 31 from below in FIG. Further, in the present embodiment, the cable support portion 40 is configured independently of the base plate 30 as a separate component.

As described above, the base plate 30 does not have to have the bottom surface portions 34A and 34B (see FIG. 3), and the assembling direction of the circuit board 24 with respect to the base plate 30 is not limited. Further, the mode of the cable support portion 40 is not particularly limited.

The actions and effects derived from the configuration of this embodiment are the same as those of the first embodiment.

10 Door handle (door handle device)
11 Handle body 12 Handle cover 13 Arm 13A Shaft hole 14 Acting part 14A Engagement recess 15 Support shaft 16 Handle lever 20 Antenna unit 21 Resin mold 21A, 21B Support convex part 21C Bottom surface 21D Top surface 21E, 21F Side surface 21G Front surface 21H Rear surface 21I Hole 22 Lock electrode (second detection electrode)
22A Plate body 22B Plate mounting piece 23 Antenna 23A Input / output cable 23B Bobbin 23C Winding conductor 23D Antenna mounting hole 24 Circuit board (proximity sensor)
24A I / O cable 24B Sensor mounting hole 24C Notch 24D Board mounting hole 25,26 Capacitor (proximity sensor) (electrode pair)
27 Low-rigidity part 30 Base plate 31 Circuit board housing part 31A Opening 32 Antenna housing part 32A Opening 33 Elastic flat plate part 34A, 34B Bottom part 35 Drive electrode (electrode pair)
35A, 35B electrode 36 unlock electrode (first detection electrode) (electrode pair)
36A, 36B Electrode 37A, 1st connecting part 37B 2nd connecting part 37C 3rd connecting part 38 Board mounting piece 39 Antenna mounting piece 40 Cable support 40A Notch 50 Finger

Claims (5)

A proximity sensor having a circuit board on which a detection circuit is printed, a drive electrode electrically connected to the detection circuit, and a first detection electrode that receives electric lines of force generated from the drive electrode.
Equipped with an antenna that sends and receives signals to and from a user-owned portable device
In the antenna, a winding conductor is wound around an insulating bobbin that houses a core made of rod-shaped ferrite.
The drive electrode and the first detection electrode is formed in both flat plate is disposed to face, and are arranged to sandwich the antenna during the previous SL drive electrode and the first detection electrode,
The bobbin has an antenna mounting hole and has an antenna mounting hole.
The circuit board has a board mounting hole and has a board mounting hole.
The drive electrode and the first detection electrode include a protruding antenna mounting piece inserted into the antenna mounting hole of the bobbin and a protruding substrate mounting piece inserted into the board mounting hole of the circuit board. An antenna unit to be equipped. Is attached to the range and the circuit board can receive electric lines of force generated from the driving electrode, further comprising a second detection electrode of the first detection shorter than the electrode length, according to claim 1 Antenna unit. The antenna unit according to claim 1 or 2 , further comprising an elastic flat plate portion in an intermediate portion between the drive electrode and the first detection electrode on which the antenna and the circuit board are not arranged. The antenna unit according to claim 3 is incorporated in the door handle of the vehicle door.
A door handle device in which the elastic flat plate portion is arranged at a position that becomes a bending point of deformation of the door handle when the user pulls the door handle. A bridge-shaped connecting portion connects the drive electrode and the first detection electrode to form an electrode pair in which a protruding antenna mounting piece and a substrate mounting piece are formed, an electrode having a bobbin in which an antenna mounting hole is formed, and detection. A circuit board on which the circuit is printed and having a substrate mounting hole, a mold for injection molding, and a cutting device provided so as to protrude in the mold are prepared.
The antenna mounting piece of the electrode pair is inserted into the antenna mounting hole of the antenna, and the antenna is mounted on the electrode pair.
The board mounting piece of the electrode pair is inserted into the board mounting hole of the circuit board, and the circuit board is mounted on the electrode pair.
The electrode pair, the antenna, and the circuit board are positioned and arranged in the mold.
The molten resin is injected into the mold to form a resin mold that covers at least the antenna and the circuit board to integrate the electrode pair, the antenna, and the circuit board, and to connect the antenna pair and the circuit board by the cutting device. A method of manufacturing an antenna unit, including cutting a part.

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