Field of the Invention. The invention relates to a shield terminal.
Related Art. A shield terminal with a built-in capacitor serving as an electronic element is used on an end part of a shielded cable (coaxial cable) in a harness, such as a radio antenna harness installed in an automotive vehicle. For example, a shield terminal of Japanese Unexamined Patent Publication No. 2006-107801 includes an electronic element having two lead wires, an inner conductor terminal connected to one of the lead wires, a dielectric for accommodating the inner conductor terminal and an outer conductor terminal accommodating the dielectric and connected to a shield conductor of a shielded cable. The other lead wire of the electronic element is connected to a core of the shielded cable. An element accommodation chamber for accommodating the electronic element penetrates through the dielectric.
In the above case, a body of the electronic element is accommodated into the element accommodation chamber of the dielectric, but nothing is present between the other lead wire and the outer conductor terminal and the other lead wire may short to the outer conductor terminal while being connected to the core of the shielded cable.
This invention was completed on the basis of the above situation and aims to provide a shield terminal capable of preventing a part of an electronic element connected to a shielded cable from shorting to an outer conductor terminal.
The invention is directed to a shield terminal with an inner conductor terminal and an outer conductor terminal surrounding the inner conductor terminal. The outer conductor terminal is connected to a shield of a shielded cable. A dielectric is arranged between the inner conductor terminal and the outer conductor terminal. An electronic element includes a core connecting portion to be connected to a core of the shielded cable and an inner conductor connecting portion to be connected to the inner conductor terminal. An insulating short circuit preventing member is arranged between the core connecting portion and the outer conductor terminal.
The insulating short circuit preventing member is between the core connecting portion of the electronic element and the outer conductor terminal. Thus, the core connecting portion connected to the core of the shielded cable cannot short to the outer conductor terminal.
The short circuit preventing member may be separate from the dielectric and arranged away from the dielectric. According to this configuration, the dielectric need not extend to a position corresponding to the core connecting portion and enlargement of the dielectric can be avoided. Further, the presence of the dielectric in the outer conductor terminal does not become an obstacle and a degree of freedom in design and process can be enhanced.
The outer conductor terminal may be provided with a tool insertion hole open between the short circuit preventing member and the dielectric, and the inner conductor connecting portion may be arranged to face the tool insertion hole. According to this configuration, after the inner conductor terminal and the dielectric are incorporated into the outer conductor terminal, the electronic element can be located in the outer conductor terminal and the inner conductor connecting portion and the inner conductor terminal can be connected through the tool insertion hole. The tool insertion hole is in the outer conductor terminal in this way by forming the short circuit preventing member separately from the dielectric and arranging the short circuit preventing member away from the dielectric.
The short circuit preventing member may include a support to be locked to the outer conductor terminal, and the electronic element may be placed and supported on the support. According to this configuration, the short circuit preventing member has a function of supporting the electronic element in addition to a function of preventing a short circuit of the core connecting portion and the outer conductor terminal. Thus, the configuration of the shield terminal can be simplified as compared to the case where the short circuit preventing function and the supporting function are provided separately in the shield terminal.
An embodiment of the invention is described with reference to
<Shielded Cable 90>
The shielded cable 90 is a coaxial cable and includes, as shown in
<Inner Conductor Terminal 11>
The inner conductor terminal 11 is formed, such as by bending a conductive metal plate. As shown in
The lead connecting portion 17 has left and right lead crimping pieces 21 rising from a bottom wall that is continuous with the mating connecting portion 15 to form an open barrel of U-shaped cross-section. As shown in
<Dielectric 12>
The dielectric 12 is made of synthetic resin in the form of a block, and an accommodating portion 22 penetrates the dielectric 12 in the front-rear direction, as shown in
<Outer Conductor Terminal 13>
The outer conductor terminal 13 is formed, such as by bending a conductive metal plate. As shown in
The dielectric 12 is inserted into the fitting portion 23 from behind and is retained in the fitting portion 23. As shown in
The barrel 24 has a U-shaped cross-section, as shown in
As shown in
The front ends of the side portions 29 are connected to left and right rear ends of the fitting 23. The rear ends of the side portions 29 are connected to the front ends of the wire barrel pieces 31 via left and right lateral attaching portions 35 whose heights are gradually reduced toward the rear. As shown in
As shown in
As shown in
<Electronic Element 16>
The electronic element 16 is for adjusting an electrical characteristic of the shield terminal 10 and, here, configured as a capacitor for adjusting a capacitance. As shown in
<Short Circuit Preventing Member 14>
The short circuit preventing member 14 is made of synthetic resin and includes, as shown in
As shown in
Left and right end surfaces of the support 45 include left and right end surfaces of the front projecting pieces 53 and the left and right end surfaces of the rear projecting piece 54 and are arranged along the front-rear direction. As shown in
The locking portions 46 project from rear sides of the both left and right end surfaces of the protrusion 49. The locking portions 46 are ribs of substantially triangular cross-section long in the front-rear direction, and have horizontal upper surfaces along the lateral direction.
<Assembling Method and Structure of Shield Terminal 10>
In assembling, the core connecting portion 43 of the electronic element 16 and the core 91 of the shielded cable 90 are crimped and connected by the crimping member 44 with the core connecting portion 43 and the core 91 facing each other on the same axis.
The protrusion 49 of the short circuit preventing member 14 is inserted into the mounting hole 38 of the outer conductor terminal 13. In the process of inserting the protrusion 49 into the mounting hole 38, the locking portions 46 slide on both left and right edges of the mounting hole 38 and the slits 55 are deformed to narrow a lateral width. When the protrusion 49 is inserted properly into the mounting hole 38, the slits 55 return to have an initial lateral width. Thus, the upper surfaces of the locking portions 46 are locked into contact with the lower ends of the side portions 29 (see
Subsequently, the electronic element 16 connected to the shielded cable 90, as described above, is placed on the outer conductor terminal 13 holding the short circuit preventing member 14 from above. In this way, the body 41 of the electronic element 16 is placed and supported on the supporting surface 47 of the short circuit preventing member 14, the inner conductor connecting portion 42 of the electronic element 16 is arranged between the lead crimping pieces 21 of the lead connecting portion 17 of the inner conductor terminal 11, the shield 93 exposed on the end part of the shielded cable 90 is arranged between the wire barrel pieces 31 and the sheath 94 on the end part of the shielded cable 90 is arranged between the insulation barrel pieces 32.
Further, the crimping member 44 crimped to both the core connecting portion 43 of the electronic element 16 and the core 91 of the shielded cable 90 is arranged on the rear projecting piece 54 of the short circuit preventing member 14 and between the slits 55 (see
Subsequently, unillustrated crimping tools composed of a crimper and an anvil are brought into contact with the lead connecting portion 17 and the barrel 24 to perform a crimping operation. For example, the lead connecting portion 17 is crimped by bringing the crimper and the anvil closer with the crimper arranged above the lead connecting portion 17 and the anvil arranged below the lead connecting portion 17 to deform and wind the lead crimping pieces 21 on the outer periphery of the inner conductor connecting portion 42. In this way, the lead connecting portion 17 is crimped and connected to the inner conductor connecting portion 42. In this case, the anvil can be brought into contact with a lower surface of the lead connecting portion 17 through the tool insertion hole 37 of the outer conductor terminal 13. Further, the crimper approaches the short circuit preventing member 14 in the process of pressing and deforming the lead crimping pieces 21, but can avoid interference with the short circuit preventing member 14 by entering between the front projecting pieces 53.
Similarly, corresponding crimping tools are brought into contact with the barrel 24 to crimp and connect the wire barrel pieces 31 to the shield 93 of the shielded cable 90 and to crimp and connect the insulation barrel pieces 32 to the sheath 94 of the shielded cable 90. The lead connecting portion 17, the wire barrel pieces 31 and the insulation barrel pieces 32 can be crimped in the same step. Thereafter, an unillustrated cover member for covering an opening part of the coupling 25 is mounted on the shield terminal 10. The cover is connected to the outer conductor terminal 13 and has a shielding function.
The electronic element 16 built in the shield terminal 10 is supported with both left and right sides thereof covered by the side portions 29 and a lower side thereof covered by the short circuit preventing member 14. A connecting part of the inner conductor connecting portion 42 and the lead connecting portion 17 is arranged at a position corresponding to the tool insertion hole 37 of the outer conductor terminal 13 and hardly contacts a bottom surface part of the outer conductor terminal 13.
On the other hand, the crimping member 44, which is a connecting part of the core connecting portion 43 and the core 91, is proximate to the rear bridge 34, which is the bottom surface part of the outer conductor terminal 13. However, the rear projecting piece 54 of the short circuit preventing member 14 is interposed between the crimping member 44 and the rear bridge 34, and the crimping member 44 is covered from below by the rear projecting piece 54. Thus, the crimping member 44 cannot contact and short to the outer conductor terminal 13 and reliability in transmitting a high-frequency signal can be ensured. Further, the short circuit preventing member 14 serves as a mark in positioning the electronic element 16. Furthermore, an impedance control can be performed by the short circuit preventing member 14.
Further, since the short circuit preventing member 14 has a function of supporting the electronic element 16 in addition to a function of preventing a short circuit of the electronic element 16 to the outer conductor terminal 13, the configuration of the shield terminal 10 can be simplified as compared to the case where the short circuit preventing function and the supporting function are respectively realized by separate members.
Furthermore, since the short circuit preventing member 14 is arranged away from the dielectric 12, the dielectric 12 need not extend long rearward and the dielectric 12 can be small. Particularly, by providing the short circuit preventing member 14 separately from the dielectric 12, the tool insertion hole 37 can be provided in the outer conductor terminal 13 without any trouble and the inner conductor connecting portion 42 and the lead connecting portion 17 can be connected after the inner conductor terminal 11 is incorporated into the outer conductor terminal 13 together with the dielectric 12 so that a degree of freedom in design and process can be enhanced.
Other embodiments are briefly described below.
The electronic element may be a resistor with lead wires or a diode with lead wires without being limited to the capacitor.
The connection of the core connecting portion of the electronic element to the core of the shielded cable, and the connection of the inner conductor connecting portion of the electronic element to the lead connecting portion of the inner conductor terminal are not limited to connection by welding and may be connection by soldering, resistance welding or ultrasonic welding.
The short circuit preventing member may be provided separately from a part for supporting the electronic element.
Number | Date | Country | Kind |
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2019-033599 | Feb 2019 | JP | national |