阅读说明：本技术 内导体端子及屏蔽端子 (Inner conductor terminal and shield terminal ) 是由 桥本宣仁 金村佳佑 洼田基树 康丽萍 三井翔平 山中航 春日将宣 平野蓝 于 2019-11-29 设计创作，主要内容包括：提供一种能够使阻抗匹配的内导体端子及具备内导体端子的屏蔽端子。内导体端子(10)由金属板构成,具备：筒状的第1端子部(11)及第2端子部(12),分别具有开口端；折弯部(15),其将第1端子部(11)和第2端子部(12)连接,与第1端子部(11)和第2端子部(12)各自的开口端的开口对置并将开口覆盖；突片部(13),其从第1端子部(11)中的与开口端相反的一侧的端部突出；以及引线部(14),其从第2端子部(12)中的与开口端相反的一侧的端部突出。内导体端子(10)具备一对侧部(16),一对侧部(16)以位于折弯部(15)的两侧的方式从第2端子部(12)突出,将折弯部(15)与第1端子部及第2端子部之间的间隙从两侧覆盖。(Provided are an inner conductor terminal capable of matching impedance and a shield terminal provided with the inner conductor terminal. The inner conductor terminal (10) is composed of a metal plate and is provided with: a cylindrical 1 st terminal part (11) and a cylindrical 2 nd terminal part (12) each having an opening end; a bent portion (15) which connects the 1 st terminal portion (11) and the 2 nd terminal portion (12) and covers the opening of the 1 st terminal portion (11) and the opening of the 2 nd terminal portion (12) by facing the opening; a protruding piece part (13) protruding from the end part of the 1 st terminal part (11) on the opposite side of the opening end; and a lead portion (14) protruding from an end portion of the No. 2 terminal portion (12) on the opposite side of the open end. The inner conductor terminal (10) is provided with a pair of side sections (16), wherein the pair of side sections (16) protrude from the 2 nd terminal section (12) so as to be positioned on both sides of the bent section (15), and the gaps between the bent section (15) and the 1 st and 2 nd terminal sections are covered from both sides.)

1. An inner conductor terminal formed of a metal plate, the inner conductor terminal comprising:

a cylindrical 1 st terminal portion and a cylindrical 2 nd terminal portion each having an opening end;

a bent portion connecting the 1 st terminal portion and the 2 nd terminal portion, facing the opening of the open end of each of the 1 st terminal portion and the 2 nd terminal portion, and covering the opening;

a projecting piece portion projecting from an end portion of the 1 st terminal portion on a side opposite to the open end;

a lead portion protruding from an end portion of the 2 nd terminal portion on a side opposite to the open end; and

and a pair of side portions protruding from at least one of the 1 st terminal portion and the 2 nd terminal portion so as to be positioned on both sides of the bent portion, and covering gaps between the bent portion and the 1 st terminal portion and the 2 nd terminal portion from both sides.

2. The inner conductor terminal according to claim 1, wherein the lead portion is provided so as to protrude from an outer wall portion of the 2 nd terminal portion that is continuous with the bent portion.

3. A shield terminal having the inner conductor terminal according to claim 1 or claim 2,

the shield terminal includes a dielectric body that houses the inner conductor terminal and an outer conductor terminal that surrounds the dielectric body,

the 1 st terminal portion is inserted into the receiving portion of the dielectric body from the rear, and the rear end of the side portion is exposed on the rear surface of the dielectric body.

4. The shield terminal of claim 3, wherein the outer conductor terminal has an enclosure that receives the dielectric body,

the thickness of the dielectric body defined between the inner surface of the surrounding portion and the 1 st terminal portion is constant in the front-rear direction.

Technical Field

The present invention relates to an inner conductor terminal and a shield terminal provided with the same.

Background

Patent document 1 discloses a shield terminal including an inner conductor terminal, an outer conductor terminal covering an outer periphery of the inner conductor terminal, and a dielectric body provided between the inner conductor terminal and the outer conductor terminal. The shield terminal is accommodated in a connector housing provided on a surface of the circuit board.

The inner conductor terminal includes a pin-shaped connection portion, a square press-fitting portion located behind the pin-shaped connection portion, and a terminal main body located behind the square press-fitting portion. The inner conductor terminal is inserted into the terminal receiving portion of the dielectric body from the rear. The pin-shaped connecting portion is cylindrical, protrudes forward of the dielectric body, and is connected to the counterpart terminal. The square press-fitting portion has a shape having a width wider than that of the pin-shaped connecting portion, and has a locking protrusion for locking with the dielectric body. The rear end of the terminal body is provided with a first lead portion in a bent manner. The 1 st lead portion has a first connection portion soldered to a surface of the circuit substrate. The inner conductor terminal is bent in a crank shape as a whole.

Disclosure of Invention

Problems to be solved by the invention

However, by forming the inner conductor terminal in a cylindrical shape, the impedance between the inner conductor terminal and the outer conductor terminal can be matched together with the thickness of the dielectric body. However, the inner conductor terminal described above has a bent portion in the middle, and it may be difficult to bend the cylindrical shape into the bent portion. If the cylindrical shape is broken at the bent portion and a gap is formed between the inner conductor terminal, the distance between the inner conductor terminal and the outer conductor terminal changes, and a predetermined impedance cannot be maintained. As a result, impedance mismatch may occur at the bent portion of the inner conductor terminal, and good transmission characteristics of the high-frequency signal may be impaired.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an inner conductor terminal capable of matching impedance and a shield terminal including the inner conductor terminal.

Means for solving the problems

The present invention is an inner conductor terminal composed of a metal plate, the inner conductor terminal including: a cylindrical 1 st terminal portion and a cylindrical 2 nd terminal portion each having an opening end; a bent portion connecting the 1 st terminal portion and the 2 nd terminal portion, facing the opening of the open end of each of the 1 st terminal portion and the 2 nd terminal portion, and covering the opening; a projecting piece portion projecting from an end portion of the 1 st terminal portion on a side opposite to the open end; a lead portion protruding from an end portion of the 2 nd terminal portion on a side opposite to the open end; and a pair of side portions protruding from at least one of the 1 st terminal portion and the 2 nd terminal portion so as to be positioned on both sides of the bent portion, and covering gaps between the bent portion and the 1 st terminal portion and the 2 nd terminal portion from both sides.

Effects of the invention

Since a bent portion is provided between the 1 st terminal portion and the 2 nd terminal portion, the opening of each of the 1 st terminal portion and the 2 nd terminal portion is covered by the bent portion, and the pair of side portions covers the gap between the bent portion and the 1 st terminal portion and the 2 nd terminal portion from both sides, the space portion between the 1 st terminal portion and the 2 nd terminal portion is surrounded by the bent portion and the pair of side portions. This prevents impedance mismatch between the 1 st terminal unit and the 2 nd terminal unit. As a result, impedance matching can be performed, and good high-frequency signal transmission can be supported.

Drawings

Fig. 1 is a perspective view of an inner conductor terminal in embodiment 1 of the present invention.

Fig. 2 is a perspective view of the inner conductor terminal before being bent.

Fig. 3 is a plan view of the inner conductor terminal.

Fig. 4 is a sectional view taken along line a-a of fig. 3.

Fig. 5 is a front view of the inner conductor terminal.

Fig. 6 is a development view of the chain state of the inner conductor terminal.

Fig. 7 is a side view of the shield terminal.

Fig. 8 is a sectional view taken along line B-B of fig. 7.

Fig. 9 is a sectional view of the shielded connector.

Detailed Description

Preferred embodiments of the present invention are shown below.

(1) Preferably, the lead portion is provided so as to protrude from an outer wall portion of the 2 nd terminal portion that is continuous with the bent portion. Accordingly, the distance between the outer wall portion of the 2 nd terminal portion and the outer conductor terminal can be made equal to the distance between the lead portion and the outer conductor terminal, and therefore impedance matching can be achieved also on the lead portion side.

(2) Preferably, a shield terminal includes the above-described inner conductor terminal, the shield terminal includes a dielectric body that houses the inner conductor terminal and an outer conductor terminal that surrounds the dielectric body, the 1 st terminal portion is inserted into the housing portion of the dielectric body from the rear, and the rear end of the side portion is exposed on the rear surface of the dielectric body. Accordingly, the first terminal portion 1 can be inserted into the housing portion of the dielectric body by pressing the rear end of the side portion with a finger, jig, or the like. That is, the side portion can be used as an operation portion when the inner conductor is assembled.

(3) Preferably, the outer conductor terminal has a surrounding portion that houses the dielectric body, and a thickness of the dielectric body defined between an inner surface of the surrounding portion and the 1 st terminal portion is constant in a front-rear direction. For example, when the opening portion of the housing portion is formed by reducing the diameter, the thickness of the dielectric body varies, and it is difficult to accurately match the impedance. In this respect, according to the above configuration, the thickness of the dielectric body including the opening portion of the receiving portion does not change, and the impedance can be accurately matched.

< example 1>

Embodiment 1 of the present invention will be described with reference to fig. 1 to 9. The inner conductor terminal 10 of embodiment 1 is configured as one component of the shield terminal 100. The shield terminal 100 includes a dielectric body 40 and an outer conductor terminal 60 in addition to the inner conductor terminal 10. The shield terminal 100 is received in the connector housing 80.

(connector case 80)

The connector housing 80 is made of synthetic resin, and is provided on a surface (upper surface) of the circuit board 90 as shown in fig. 9. The connector housing 80 includes a mounting portion 81 substantially along the vertical direction and a cover portion 82 protruding forward (right side in fig. 1) from the outer periphery of the mounting portion 81. The mounting portion 81 is provided with a through hole 83 penetrating in the front-rear direction.

(outer conductor terminal 60)

The outer conductor terminal 60 is integrally formed by bending a conductive metal plate. The outer conductor terminal 60 has a cylindrical surrounding portion 61 that surrounds the outer periphery of the inner conductor terminal 10. The surrounding portion 61 is disposed so that the axis thereof faces the front-rear direction, and is inserted from the front into and connected to a counterpart outer conductor terminal, not shown. The counterpart outer conductor terminal is connected to a shield layer of a shield wire, not shown.

As shown in fig. 8, a pair of locking pieces 62 is provided on the surrounding portion 61 so as to protrude to the left and right. The outer conductor terminal 60 is inserted into the through hole 83 of the mounting portion 81 in a penetrating state, and is mounted to the connector housing 80 by locking the two locking pieces 62 to the mounting portion 81. As shown in fig. 9, the front portion of the surrounding portion 61 is disposed so as to protrude into the cover portion 82.

As shown in fig. 7 and 9, a pair of connecting pieces 63 (only one of which is shown in fig. 7 and 9) that extend downward and are bent rearward are provided at a lower portion of the rear end of the outer conductor terminal 60. Each connecting piece 63 is connected by soldering to a ground portion, not shown, formed on the surface of the circuit board 90. The opening of the rear surface of the outer conductor terminal 60 is closed by a flat plate-like cover portion 64.

(dielectric body 40)

The dielectric member 40 is made of synthetic resin, has a block shape, and is inserted and housed from the rear into the surrounding portion 61 of the outer conductor terminal 60 as shown in fig. 9. The dielectric body 40 has a housing portion 41 penetrating in the front-rear direction. As shown in fig. 8, the accommodating portion 41 is opened in a substantially concentric circular shape with the arc-shaped peripheral wall portion 65 of the surrounding portion 61 in a state where the dielectric body 40 is accommodated in the surrounding portion 61. The housing 41 penetrates with the same diameter over the entire length in the front-rear direction.

As shown in fig. 8 and 9, an insertion portion 42 into which a 2 nd terminal portion 12, a bent portion 15, and a pair of side portions 16 of the inner conductor terminal 10, which will be described later, can be inserted is provided at the rear portion of the dielectric body 40. The insertion portion 42 is open at the rear and lower sides. A wall portion 43 protruding downward is provided at the lower end of the rear portion of the dielectric body 40. As shown in fig. 9, the wall portion 43 has a vertical wall shape extending in the vertical direction, and closes the front of the insertion portion 42. The wall portion 43 is disposed so as to substantially abut against the lower end rear edge of the surrounding portion 61 of the outer conductor terminal 60 and the step surface 84 of the mounting portion 81 of the connector housing 80. The dielectric member 40 is locked by a locking claw 66 (see fig. 7) protruding into the surrounding portion 61 of the outer conductor terminal 60, and is held in the surrounding portion 61 so as to be prevented from coming off.

(inner conductor terminal 10)

The inner conductor terminal 10 is integrally formed by bending a conductive metal plate (see fig. 6) or the like. As shown in fig. 1 to 5, the inner conductor terminal 10 includes a 1 st terminal portion 11, a 2 nd terminal portion 12, a projecting portion 13, a lead portion 14, a bent portion 15, and a pair of side portions 16.

The 1 st terminal portion 11 is cylindrical, specifically, cylindrical, and is disposed so that its axis line is oriented in the front-rear direction. As shown in fig. 9, the 1 st terminal portion 11 is inserted from the rear into the receiving portion 41 received in the dielectric body 40. The 1 st terminal portion 11 has a guide portion 17 tapered and reduced in diameter toward the front at a front end portion. As shown in fig. 3 to 5, a pair of locking portions 18 are provided in the middle portion of the 1 st terminal portion 11 in the front-rear direction so as to protrude to both the left and right sides. Each locking portion 18 is cut and punched out of the 1 st terminal portion 11 through a slit 19 (see fig. 1 to 3) extending in the vertical direction. The 1 st terminal portion 11 has a shape extending with the same diameter in the front-rear direction except for the guide portion 17 and the locking portion 18. The outer diameter of the 1 st terminal portion 11 (the outer diameter of the portion other than the guide portion 17 and the locking portion 18) is the same as the inner diameter of the housing 41 or slightly smaller than the inner diameter of the housing 41. In a state where the 1 st terminal portion 11 is accommodated in the accommodating portion 41, the guide portion 17 is disposed so as to face the front end opening of the accommodating portion 41.

As shown in fig. 1 and 2, the rear end of the 1 st terminal portion 11 is configured as a 1 st opening end 21 which is circular in rear view. The opening of the 1 st opening end 21 is open at the rear and closed by the bent portion 15 except for the left and right sides.

The protruding piece portion 13 is formed in a cylindrical shape extending forward from the front end of the guide portion 17. The front end of the protruding piece 13 is narrowed and closed. The projecting piece portion 13 is formed in a shape extending with the same diameter in the front-rear direction except for the front end portion. As shown in fig. 9, the entire projecting piece 13 projects forward from the front end of the dielectric body 40 and is surrounded by the surrounding portion 61 of the outer conductor terminal 60. The projecting piece 13 is inserted into a box portion connected to the inner conductor terminal on the other side, not shown.

As shown in fig. 5, the 1 st terminal portion 11 and the projecting piece portion 13 include abutting edges 22 extending over the entire length in the front-rear direction at the left and right center portions of the lower ends. The projecting piece portion 13 and the 1 st terminal portion 11 are curved in an arc shape and butted at the butted edge 22, so that the cylindrical shape of the projecting piece portion 13 and the 1 st terminal portion 11 can be maintained.

The 2 nd terminal portion 12 has a cylindrical shape, specifically a rectangular cylindrical shape, and is disposed so that its axis line is directed in the vertical direction. As shown in fig. 1, the 2 nd terminal portion 12 includes: an outer wall portion 23 disposed facing rearward; a side wall portion 24 bent forward from one side edge (left side edge in fig. 1) of the outer wall portion 23 and disposed toward one side (left side in fig. 4) as shown in fig. 4; an inner wall portion 25 bent from a front end edge of the one side wall portion 24 to the other side (right side in fig. 4) and disposed forward; and a second side wall 26 bent rearward from a second side edge (a right side edge in fig. 4) of the inner wall 25 and disposed toward the other side. The outer wall portion 23, the one side wall portion 24, the inner wall portion 25, and the other side wall portion 26 are formed in a substantially rectangular flat plate shape that is long in the vertical direction.

As shown in FIG. 1, a side surface concave portion 27 having a shape of L letter-like cutout in side view is provided on the upper portion of the rear end edge of the other side wall portion 26, a rear surface concave portion 28 having a shape of L letter-like cutout in rear view is provided on the lower portion of the other side edge of the outer wall portion 23, the upper portion of the other side edge of the outer wall portion 23 is fitted into the side surface concave portion 27 of the other side wall portion 26, and the lower portion of the rear end edge of the other side wall portion 26 is fitted into the rear surface concave portion 28 of the outer wall portion 23. thus, the other side edge of the outer wall portion 23 and the rear end edge of the other side wall portion 26 are engaged in a concave-convex manner, whereby the rectangular tubular shape of the terminal portion 2 can be maintained, and as shown in FIG. 9, the front surface.

As shown in fig. 1 and 3, the upper end of the 2 nd terminal portion 12 is configured as a 2 nd open end 29 having a rectangular shape in plan view. The opening of the 2 nd opening end 29 is opened at the upper part and closed by the bent part 15 except the left and right sides. As shown in fig. 4, the lower end of the 2 nd terminal portion 12 is configured to have a rectangular lower open end 31 when viewed from above. The opening of the lower open end 31 is open downward.

As shown in fig. 1, the lead portion 14 is integrally and continuously provided with the outer wall portion 23 of the 2 nd terminal portion 12. The lead portion 14 is in the form of a strip, and extends by being bent rearward after protruding downward from the outer wall portion 23. The width of the lead portion 14 is smaller than the width of the outer wall portion 23 (2 nd terminal portion 12). As shown in fig. 9, the lower surface of the lead portion 14 is disposed along the surface of the circuit board 90, and is connected to a conductive portion 91 formed on the surface of the circuit board 90 by soldering. The lead portion 14 and the respective connecting pieces 63 of the outer conductor terminal 60 are arranged in a left-right array.

Bent portion 15 is disposed between 1 st terminal portion 11 and 2 nd terminal portion 12. As shown in fig. 1, the bent portion 15 has a band-plate shape bent from a front end to a lower end, the front end being integrally connected to a rear end (1 st opening end 21) of an upper portion of the 1 st terminal portion 11, and the lower end being integrally connected to an upper end (2 nd opening end 29) of the outer wall portion 23 of the 2 nd terminal portion 12. First terminal portion 11 and second terminal portion 12 are connected by bent portion 15. The width of the bent portion 15 is slightly smaller than the width of the outer wall portion 23 (the 2 nd terminal portion 12) and is substantially the same as the width of the lead portion 14.

The bent portion 15 is bent from a linear state shown in fig. 2 where the 1 st terminal portion 11 and the 2 nd terminal portion 12 are located at positions arranged in the front-rear direction to a bent state shown in fig. 1 where the 1 st terminal portion 11 and the 2 nd terminal portion 12 are located at positions substantially orthogonal to each other.

A portion (reference numeral a in fig. 1) of the bent portion 15 extending rearward from the upper portion of the 1 st terminal portion 11 is disposed so as to face the opening of the 2 nd open end 29 of the 2 nd terminal portion 12 so as to cover the opening of the 2 nd open end 29 from above, and a portion (reference numeral b in fig. 1) extending upward from the outer wall portion 23 of the 2 nd terminal portion 12 is disposed so as to face the opening of the 1 st open end 21 of the 1 st terminal portion 11 so as to cover the opening of the 1 st open end 21 from behind.

As shown in fig. 1 and 3 to 5, the pair of side portions 16 are integrally connected to the upper ends (the 2 nd opening end 29) of the one side wall portion 24 and the other side wall portion 26 of the 2 nd terminal portion 12, and protrude upward from the upper ends of the one side wall portion 24 and the other side wall portion 26.

As shown in fig. 1, each side portion 16 is in the form of a flat plate having a rectangular shape in side view, and is disposed so as to cover the inside of the bent portion 15 from both the left and right sides across the bent portion 15. Specifically, each side portion 16 is disposed so as to cover and close a space portion formed between bent portion 15, 1 st terminal portion 11, and 2 nd terminal portion 12 from both left and right sides.

As shown in fig. 4 and 5, the upper end of each side portion 16 is disposed at a position substantially equal to the upper end of the bent portion 15 or slightly higher than the upper end of the bent portion 15. The inner surface of each side portion 16 is formed as a flat surface extending in the vertical direction (height direction) and the horizontal direction (width direction), and is disposed away from both the left and right ends of the bent portion 15 as shown in fig. 8. The rear end surface 32 of each side portion 16 is formed as a plate thickness surface along the vertical direction, and functions as an operation surface pressed by a finger or a jig when the inner conductor terminal 10 is assembled to the dielectric body 40.

As shown in fig. 6, a formation region P1 of each side portion 16 and a formation region P2 of the bent portion 15 when the inner conductor terminal 10 is spread out (before bending) are arranged in a formation region P5 of the 2 nd open end 29 between formation regions P3 and P4 of the 1 st terminal portion 11 and the 2 nd terminal portion 12, respectively. Therefore, waste of material for the metal plate can be reduced when forming each side portion 16.

Next, the operation and effect of embodiment 1 will be described.

The inner conductor terminal 10 is assembled to the dielectric body 40 from the rear. The 1 st terminal 11 is inserted into a receiving portion 41 of the dielectric body 40, and the 2 nd terminal 12, the bent portion 15, and each side portion 16 are inserted into an insertion portion 42 of the dielectric body 40. Each side portion 16 is disposed along the height direction in the insertion portion 42 of the dielectric body 40 and can be visually recognized from the rear (see fig. 8). When assembling, the rear end surfaces 32 of the side portions 16 are pressed by fingers or jigs, so that the 1 st terminal portions 11 can be smoothly inserted into the receiving portions 41. The insertion operation of the inner conductor terminal 10 can be restricted by the inner wall portion 25 of the 2 nd terminal portion 12 abutting against the wall portion 43 of the dielectric body 40. Further, the engagement portions 18 of the inner conductor terminal 10 are engaged with the inner peripheral surface of the housing portion 41 by being caught, whereby the inner conductor terminal 10 can be restricted from falling off from the housing portion 41.

In a state where the inner conductor terminal 10 is normally assembled to the dielectric body 40, the 1 st terminal portion 11 is housed in the housing portion 41 over substantially the entire length in the front-rear direction, and is disposed so that substantially the entire circumference in the circumferential direction can be in contact with the housing portion 41 (see fig. 9). The projecting piece 13 is disposed so as to project forward from the front end of the dielectric body 40 as a whole. The guide portion 17 of the 1 st terminal portion 11 is also disposed so as to protrude forward from the front end of the dielectric body 40, except for the rear end portion. The inner conductor terminal 10 is disposed so as to penetrate a substantially central portion (a radially central portion) of the dielectric body 40 as a whole.

The dielectric body 40 is assembled to the outer conductor terminal 60 from the rear. Before the dielectric body 40 is assembled, the cover 64 is retracted and the opening of the rear surface of the outer conductor terminal 60 is opened. The dielectric body 40 is held by the locking claws 66 in the surrounding portion 61 of the outer conductor terminal 60 and is disposed so as to be in contact with the surrounding portion 61 substantially along the inner peripheral surface thereof. After the dielectric body 40 is assembled, the outer conductor terminal 60 has its opening on the rear surface closed by the lid 64. Then, the outer conductor terminal 60 is inserted and held into the through-hole 83 of the connector housing 80 from the rear (see fig. 9). A mating side contact housing, not shown, is fitted into the hood 82, a mating side outer conductor end, not shown, is connected to the outer conductor terminal 60, and a mating side inner conductor terminal, not shown, is connected to the inner conductor terminal 10.

As shown in fig. 9, the 1 st terminal portion 11 is coaxially disposed with the protruding portion 13 at a substantially central portion (radially central portion) within the surrounding portion 61 of the outer conductor terminal 60. Therefore, the radial distance D1 (corresponding to the thickness of the dielectric body 40) between the outer peripheral surface of the 1 st terminal portion 11 and the surrounding portion 61 is substantially constant in the front-rear direction. The distance D2 between the outer wall portion 23 of the 2 nd terminal portion 12 and the lid portion 64 is approximately equal to the distance D1, and is approximately constant in the vertical direction. Even though the bent portion 15 is interposed between the outer wall portion 23 of the 2 nd terminal portion 12 and the upper portion of the 1 st terminal portion 11, the distance D2 does not greatly differ between the bent portion 15 and the outer conductor terminal 60.

The distance D3 (see fig. 8) between the one side wall portion 24 and the other side wall portion 26 of the 2 nd terminal portion 12 and the side surface portion of the outer conductor terminal 60 is also approximately equal to the distance D2 and is approximately constant in the vertical direction. The side portions 16 are provided so as to protrude from the upper ends of the one side wall portion 24 and the other side wall portion 26, and the distance D3 does not greatly differ between the side portions 16 and the side surface portion of the outer conductor terminal 60.

Therefore, the distance between the inner conductor terminal 10 and the outer conductor terminal 60 does not vary greatly over the entire region from the 1 st terminal portion 11 to the 2 nd terminal portion 12. Therefore, a predetermined impedance can be maintained between the inner conductor terminal 10 and the outer conductor terminal 60.

Particularly, in the case of embodiment 1, the space portion formed between the 1 st open end 21 of the 1 st terminal portion 11 and the 2 nd open end 29 of the 2 nd terminal portion 12 is covered and closed by the bent portion 15 and the side portions 16. Specifically, the bent portion 15 is disposed so as to cover the openings of the 1 st opening end 21 and the 2 nd opening end 29 at positions facing the openings (see reference numerals a and b in fig. 1), and the side portions 16 located on both sides of the bent portion 15 are disposed so as to cover the above-described space portions from both sides. Therefore, it is possible to prevent a gap that opens in the rear and left-right directions from being formed in the bent portion between the 1 st terminal portion 11 and the 2 nd terminal portion 12, and to achieve impedance matching even in the bent portion. As a result, the transmission characteristics of the high-frequency signal can be improved.

Further, since the lead portion 14 is provided in the 2 nd terminal portion 12 so as to protrude from the outer wall portion 23 connected to the bent portion 15, the distance between the outer wall portion 23 of the 2 nd terminal portion 12 and the lid portion 64 of the outer conductor terminal 60 can be made equal to the distance between the lead portion 14 and the lid portion 64 of the outer conductor terminal 60, and impedance matching can be achieved also on the lead portion 14 side.

Further, although the receiving portion 41 has a shape in which the diameter is reduced on the tip side of the dielectric body 40 in the related art, in the case of embodiment 1, the receiving portion 41 penetrates the dielectric body 40 with the same diameter in the front-rear direction, and the thickness of the dielectric body 40 does not change, so that impedance matching can be achieved also on the tip side of the dielectric body 40.

< other examples >

Other embodiments will be briefly described below.

(1) The 1 st terminal portion may be formed in a square tube shape.

(2) The 2 nd terminal portion may be formed in a cylindrical shape.

(3) Each side portion may protrude from the 2 nd terminal portion and be positioned on both sides of the bent portion.

(4) Each side portion may protrude from both the 1 st terminal portion and the 2 nd terminal portion and be positioned on both sides of the bent portion.

(5) Each side portion may be disposed so as to contact both left and right ends of the bent portion.

Description of the reference numerals

10: inner conductor terminal

11: 1 st terminal part

12: 2 nd terminal part

13: projecting piece part

14: lead wire part

15: bent part

16: side part

21: 1 st open end

23: outer wall part

29: 2 nd open end

40: dielectric body

41: storage part

60: outer conductor terminal

100: shielding terminal