JP7248140B2 - coaxial connector - Google Patents

Description

This invention relates to coaxial connectors.

For example, each of the coaxial cable connectors of Patent Documents 1 and 2 includes an inner terminal (socket) connected to the center conductor of the coaxial cable, an outer terminal (housing) connected to the outer conductor of the coaxial cable, and an inner terminal and an insulating member (bushing) arranged between the external terminals.

In the coaxial cable connector, the external terminal includes a tubular portion, a supporting arm portion, and a lid portion, and the tubular portion and the lid portion are connected to each other by a bending portion so as to be bendable. The lid is configured to cover the tubular portion and the support arm when bent. The coaxial cable connector discloses that the fixing portion and the extension portion provided on the lid portion are bent along the supporting arm portion and crimped to engage the supporting arm portion to surround and fix the supporting arm portion.

JP 2015-15175 A JP 2015-15176 A

In Patent Documents 1 and 2, the contact position between the cover portion, the cylindrical portion, and the support arm portion is likely to change, and as a result, electromagnetic resonance occurs at a frequency related to the contact position. A resonance point occurs in the insertion loss waveform.

SUMMARY OF THE INVENTION An object of the present invention is to provide a coaxial connector that prevents electromagnetic resonance and prevents occurrence of resonance points in the insertion loss waveform.

In order to solve the above problems, a coaxial connector according to one aspect of the present invention includes:
an inner terminal connected to the center conductor of the coaxial cable;
a first external connection portion connected to an external conductor of the coaxial cable; a second external connection portion disposed so as to surround the internal terminal; and connecting the first external connection portion and the second external connection portion. an external terminal having a connecting portion for
A coaxial connector comprising an insulating member arranged between the internal terminal and the external terminal,
The second external connection portion has a tubular portion and an extension portion extending from the tubular portion,
The first external connection portion includes a lid portion configured to cover the cylindrical portion and the extension portion when viewed from the insertion/removal direction, and a crimping engagement for bending and crimping the extension portion so as to cover the extension portion. and
A contact convex portion for contacting the first surface of the lid portion and the second surface of the second external connection portion facing the first surface is disposed between the connecting portion and the crimping engagement portion. It is

According to this aspect of the invention, the contact projection provided between the connecting portion and the crimping engagement portion ensures reliable contact between the lid portion and the second external connection portion, and the contact position is uniquely defined. can be defined Therefore, by arranging the contact protrusion at a position that does not resonate in the high frequency band to be used, it is possible to prevent electromagnetic resonance in the high frequency band and to prevent occurrence of resonance points in the insertion loss waveform.

1 is a perspective view of a coaxial connector set according to a first embodiment; FIG. 2 is a perspective view of the coaxial connector set shown in FIG. 1 in a non-fitted state; FIG. 2 is a perspective view of a mating connector that constitutes the coaxial connector set shown in FIG. 1; FIG. FIG. 2 is a perspective view of the coaxial connectors constituting the coaxial connector set shown in FIG. 1 in an un-crimped state; 5 is a side view of the coaxial connector shown in FIG. 4; FIG. 5 is a perspective view of the coaxial connector shown in FIG. 4 in a crimped state; FIG. FIG. 4 is a perspective view of a second external connection portion in an external terminal that constitutes the coaxial connector; FIG. 8 is a side view of the second external connection portion shown in FIG. 7; FIG. 4 is a perspective view of a first external connection portion in an external terminal that constitutes the coaxial connector; FIG. 10 is a side view of the first external connection portion shown in FIG. 9; It is a figure explaining the cross-sectional structure of the external terminal of a coaxial connector. FIG. 10 is a diagram illustrating a first external connection portion in an external terminal of a coaxial connector according to a second embodiment; FIG. 10 is a diagram illustrating a second external connection portion in an external terminal of a coaxial connector according to a third embodiment; FIG. 11 is a diagram illustrating a second external connection portion in an external terminal of a coaxial connector according to a fourth embodiment;

An embodiment of an L-shaped coaxial connector 10 according to the present invention will be described below with reference to the drawings. For convenience of explanation, each drawing shows an X-axis, a Y-axis, and a Z-axis that are orthogonal to each other.

[Coaxial connector set]
FIG. 1 is a perspective view of a coaxial connector set 1 according to the first embodiment. FIG. 2 is a perspective view of the coaxial connector set 1 shown in FIG. 1 in a non-fitted state.

As shown in FIG. 1 , the coaxial connector set 1 includes an L-shaped coaxial connector (coaxial connector) 10 and a mating connector 20 . The L-shaped coaxial connector 10 is configured to fit into the mating connector 20 so as to be insertable and removable in the insertion/removal direction (Z-axis direction). In the coaxial connector set 1 shown in FIG. 2, the L-shaped coaxial connector 10 is opposed to the mating connector 20, and the mating connector 20 is moved toward the mating connector 20 in the insertion/removal direction (the Z-axis direction). The coaxial connector 10 and the mating connector 20 are fitted together. While the L-shaped coaxial connector 10 is connected to the coaxial cable 40, the mating connector 20 is mounted on a circuit board (not shown).

[Mating connector]
As shown in FIG. 3 , the mating connector 20 includes a mating internal terminal (center pin) 24 , a mating external terminal 26 , and a mating insulating member (resin) disposed between the mating internal terminal 24 and the mating external terminal 26 . mold) 22.

The counterpart internal terminal 24 is a terminal connected to a signal land portion of a circuit board (not shown). The counterpart internal terminal 24 is electrically insulated from the counterpart external terminal 26 by the counterpart insulating member 22 .

The counterpart internal terminal 24 is made of a conductive member. The mating internal terminal 24 is made of, for example, a single metal plate such as a copper alloy material, and its surface is plated with nickel and gold. The counterpart internal terminal 24 is integrated with the counterpart insulating member 22 by insert molding. According to this configuration, the positioning between the counterpart insulating member 22 and the counterpart internal terminal 24 can be performed accurately.

The mating internal terminal 24 includes a mating internal contact portion 24a and a mating internal mounting portion 24b (illustrated by a dashed line). The counterpart internal terminal 24 is bent in an L shape when viewed in cross section.

The counterpart inner contact portion 24a extends in the insertion/removal direction (Z-axis direction). The mating inner contact portion 24a has a substantially cylindrical shape. The mating internal contact portion 24a contacts and is electrically connected to the internal contact portion 14a of the internal terminal 14 of the L-shaped coaxial connector 10 . The counterpart internal contact portion 24a shown in FIG. 3 is configured as a male type (pin type) having a contact surface on the outer peripheral portion. The counterpart internal mounting portion 24b is electrically connected to a signal land portion of a circuit board (not shown) by a conductive member such as solder.

The mating external terminal 26 is a terminal connected to a grounding land portion of a circuit board (not shown). The mating external terminal 26 is made of a conductive member. The mating external terminal 26 is made of, for example, a single metal plate such as a copper alloy material, and its surface is plated with nickel and gold. The mating external terminal 26 is integrated with the mating insulating member 22 by insert molding. According to this configuration, the positioning between the counterpart insulating member 22 and the counterpart external terminal 26 can be performed accurately.

The mating external terminal 26 includes a mating external mounting portion 26a and a mating second external connecting portion 26b. The mating external mounting portion 26a is electrically connected to a grounding land portion of a circuit board (not shown) by a conductive member such as solder.

The mating second external connection portion 26b extends in the insertion/removal direction (Z-axis direction). The mating second external connection portion 26b has a substantially cylindrical shape. The counterpart second external connection portion 26b is arranged coaxially with the counterpart internal contact portion 24a. The mating second external connection portion 26b contacts and is electrically connected to the second external connection portion 16b of the external terminal 16 of the L-shaped coaxial connector 10 . A fitting recess 26h is formed on the outer peripheral surface of the mating second external connection portion 26b. When the L-shaped coaxial connector 10 is fitted to the mating connector 20, the mating concave portion 26h of the mating second external connection portion 26b fits with the mating convex portion 16h of the second external connecting portion 16b.

[L-shaped coaxial connector]
FIG. 4 is a perspective view of the L-shaped coaxial connector 10, which constitutes the coaxial connector set 1 shown in FIG. 1, in an uncrimped state. FIG. 5 is a side view of the L-shaped coaxial connector 10 shown in FIG. FIG. 6 is a perspective view of the L-shaped coaxial connector 10 shown in FIG. 4 in a crimped state. 7 is a perspective view of the second external connection portion 16b of the external terminal 16 that constitutes the L-shaped coaxial connector 10. FIG. FIG. 8 is a side view of the second external connection portion 16b shown in FIG. 9 is a perspective view of the first external connection portion 16a of the external terminal 16 that constitutes the L-shaped coaxial connector 10. FIG. FIG. 10 is a side view of the first external connection portion 16a shown in FIG. FIG. 11 is a diagram illustrating the cross-sectional structure of the external terminal 16 of the L-shaped coaxial connector 10. As shown in FIG. 7 to 10, the first external connection portion 16a and the second external connection portion 16b are shown separated at the connecting portion 16f for easy understanding of the configuration of the external terminal 16. It is However, in the external terminal 16, the first external connection portion 16a and the second external connection portion 16b are integrally connected by the connecting portion 16f.

As shown in FIG. 6 , the L-shaped coaxial connector 10 has an insulating member (bushing) 12 , an internal terminal (center socket) 14 and an external terminal (housing) 16 .

The internal terminal 14 is a terminal connected to the center conductor 42 of the coaxial cable 40 . The internal terminal 14 is electrically insulated from the external terminal 16 by the insulating member 12 .

The internal terminal 14 is composed of a conductive member. The internal terminal 14 is made of, for example, a sheet of metal plate such as a copper alloy material, and its surface is plated with nickel and gold. The internal terminal 14 is integrated with the insulating member 12 by insert molding. According to this configuration, the positioning between the insulating member 12 and the internal terminal 14 can be performed accurately.

The internal terminal 14 includes an internal contact portion 14a and a central conductor connection portion (not shown). The internal terminal 14 is bent in an L shape when viewed in cross section.

The inner contact portion 14a extends in an axial direction perpendicular to the extending direction of the coaxial cable 40, that is, in the insertion/removal direction (Z-axis direction). The inner contact portion 14a has a substantially cylindrical shape in which a plurality of portions are partially notched in the circumferential direction.

The internal contact portion 14 a electrically contacts the counterpart internal contact portion 24 a of the counterpart internal terminal 24 of the counterpart connector 20 . The internal contact portion 14a shown in FIG. 6 is configured as a female type (socket type) having a contact surface on the inner peripheral portion.

The central conductor connecting portion extends in the extending direction of the coaxial cable 40, that is, in the lateral direction (X-axis direction) orthogonal to the insertion/removal direction. The center conductor connecting portion is a plate-shaped terminal portion extending laterally from the inner contact portion 14a. The central conductor connecting portion is electrically connected to the central conductor 42 of the coaxial cable 40 .

The external terminal 16 is a terminal connected to the external conductor 41 of the coaxial cable 40 . The external terminal 16 is composed of a conductive member. The external terminal 16 is made of, for example, a single metal plate such as a copper alloy material, and its surface is plated with nickel and gold.

The external terminal 16 includes a first external connection portion 16a, a second external connection portion 16b, and a connecting portion 16f. The first external connection portion 16a and the second external connection portion 16b are connected by a connecting portion 16f provided on the side opposite to the side on which the coaxial cable 40 is arranged.

The first external connection portion 16a extends in the lateral direction (X-axis direction) from the connecting portion 16f and has a plate shape. The first external connection portion 16 a is positioned along the top surfaces of the insulating member 12 and the coaxial cable 40 to hold the insulating member 12 and the coaxial cable 40 after assembly.

The first external connection portion 16a has a lid portion 16i, an external conductor caulking portion 16s, and an external coating crimping portion 16t.

The lid portion 16i has a flat plate shape and extends from the connecting portion 16f toward the external conductor caulked portion 16s. The lid portion 16i in the closed state is configured to cover the cylindrical portion 16d and the extension portion 16g when viewed from the insertion/removal direction (Z-axis direction). The lid portion 16i has a first surface 16m on the side facing the cylindrical portion 16d of the second external connection portion 16b. The lid portion 16i has a pair of crimping engagement portions 16c at side ends in the width direction (Y-axis direction). As shown in FIG. 11, each crimping engagement portion 16c is configured to cover the crimping guide portion 16p of the extension portion 16g. Each crimping engagement portion 16c is configured to be bent and crimped along the crimping guide portion 16p.

Each caulking engagement portion 16c extends in the insertion/removal direction (Z-axis direction) from the side end portion of the lid portion 16i. Each of the caulking engagement portions 16c is composed of plate-like members formed to face each other in the width direction (Y-axis direction). Each crimping engagement portion 16c contacts the outer conductor 41 of the coaxial cable 40 by bending and crimping the extension portion 16g so as to cover the crimping guide portion 16p. Thereby, the external terminal 16 and the external conductor 41 are electrically connected.

The outer conductor crimped portion 16 s is electrically connected to the outer conductor 41 of the coaxial cable 40 by crimping the outer conductor 41 while surrounding the outer conductor 41 . The crimping portion 16 t of the outer covering is fixed to the outer covering 43 by crimping the outer covering 43 of the coaxial cable 40 while surrounding the outer covering 43 .

The second external connection portion 16b has a tubular portion 16d, an extension portion 16g, a retaining portion 16e, and a crimping guide portion 16p. A second surface 16n is formed on the upper surface of the second external connection portion 16b, that is, the upper surfaces of the cylindrical portion 16d and the extension portion 16g. When the connecting portion 16f is bent so that the first external connection portion 16a faces the second external connection portion 16b, the first surface 16m faces the second surface 16n. The cylindrical portion 16d of the second external connection portion 16b is fitted to the mating external terminal 26 of the mating connector 20 . The cylindrical portion 16d extends in the insertion/removal direction (Z-axis direction). The cylindrical portion 16d has an opening on the side where the coaxial cable 40 is arranged, that is, on the side opposite to the connecting portion 16f when viewed from the insertion/removal direction (Z-axis direction). The inner holding portion 12a of the insulating member 12 is inserted into the cylindrical portion 16d through the opening of the cylindrical portion 16d. According to this configuration, stable fitting can be obtained while suppressing deformation of the cylindrical portion 16d. In the assembled state shown in FIG. 6, the internal contact portion 14a of the internal terminal 14 is positioned inside the cylindrical portion 16d. At this time, the cylindrical portion 16d is positioned so as to be coaxial with the inner contact portion 14a.

The cylindrical portion 16d has an arc shape formed by partially notching the side of the coaxial cable 40 (opposite side of the connecting portion 16f) in the circumferential shape when viewed from the insertion/removal direction (Z-axis direction). doing The extending portion 16g extends along the extending direction of the coaxial cable 40 . The tubular portion 16d and the extension portion 16g meet at the bent portion 16k. A caulking guide portion 16p is provided on the coaxial cable 40 side of the extension portion 16g (opposite side of the connecting portion 16f). Therefore, the extending portion 16g extends from the bent portion 16k to the caulking guide portion 16p in the lateral direction (X-axis direction).

The retaining portion 16e is provided below the extension portion 16g. The retaining portion 16e extends in the insertion/removal direction (Z-axis direction) from the extension portion 16g. The retaining portion 16e is composed of a pair of plate-like members formed to face each other in the width direction (Y-axis direction). By bending and crimping the retaining portion 16e, the crimped portion of the retaining portion 16e engages with the retaining concave portion of the central conductor holding portion 12b. According to this configuration, the retaining portion 16e prevents the central conductor holding portion 12b of the insulating member 12 from coming off in the insertion/removal direction (Z-axis direction), and the insulating member 12 is held and fixed to the external terminal 16. be done.

As shown in FIG. 7, a plurality of (for example, four) positioning portions 17 are evenly arranged in the circumferential direction on the inner surface portion of the cylindrical portion 16d. The positioning portion 17 is a convex portion (for example, hemispherical shape) that protrudes radially inward from the inner surface portion toward the outer surface portion of the internal holding portion 12a. The positioning portion 17 is positioned between the fitting convex portion 16h and the second surface 16n in the insertion/removal direction (Z-axis direction). The positioning portion 17 is configured to come into contact with the outer surface portion of the internal holding portion 12a. According to this configuration, since the convex positioning portion 17 functions as a reinforcing member, the cylindrical portion 16d of the external terminal 16 is less likely to deform.

Insulating member 12 is positioned between inner terminal 14 and outer terminal 16 . The insulating member 12 is made of an electrically insulating resin (for example, liquid crystal polymer), and electrically insulates the internal terminals 14 and the external terminals 16 from each other.

As shown in FIG. 6, the insulating member 12 includes an internal holding portion 12a and a central conductor holding portion 12b.

The internal holding portion 12a has a substantially circular shape when viewed from the insertion/removal direction (Z-axis direction). The inner holding portion 12a is sized so as to be mountable inside the cylindrical portion 16d in the inserting/removing direction (Z-axis direction) through the opening of the cylindrical portion 16d. In the internal holding portion 12a, the internal contact portion 14a of the internal terminal 14 protrudes in the insertion/extraction direction (Z-axis direction). The internal contact portion 14a is integrated with the internal holding portion 12a so as to be coaxial with the internal holding portion 12a. For example, by insert molding, the inner contact portion 14a is integrated with the inner holding portion 12a, and part of the central conductor connection portion is integrated with the inner holding portion 12a. According to this configuration, the positioning between the insulating member 12 and the internal terminal 14 can be performed accurately.

The central conductor holding portion 12b extends from the inner holding portion 12a toward the coaxial cable 40 in the lateral direction (X-axis direction). The center conductor holding portion 12b has a substantially rectangular shape when viewed from the insertion/removal direction (Z-axis direction). The remainder of the central conductor connecting portion is embedded in the central conductor holding portion 12b and exposed from the central conductor holding portion 12b. The exposed end of the central conductor connecting portion is electrically connected to the central conductor 42 .

[First embodiment]
As shown in FIGS. 7 and 8, a plurality of (for example, two) contact protrusions 30 are arranged in the circumferential direction on the second surface 16n of the tubular portion 16d and the extension portion 16g. By providing the contact protrusion 30 on the second external connection portion 16b, the contact protrusion 30 can be easily formed. As shown in FIG. 11, the contact projection 30 is provided between the connecting portion 16f and the crimping engagement portion 16c. A contact protrusion 30 is provided on the second surface 16n of the cylindrical portion 16d. According to this configuration, since the contact protrusion 30 is positioned away from the crimping engagement portion 16c, reliable contact by the contact protrusion 30 can be obtained, and the contact position can be uniquely defined.

Each contact protrusion 30 has a rectangular shape when viewed from the width direction (Y-axis direction) orthogonal to the insertion/removal direction (Z-axis direction), and protrudes upward at a height H from the second surface 16n. In the circumferential direction of the second surface 16n of the cylindrical portion 16d, the side end portion of the connecting portion 16f and the side end portion of the contact protrusion 30 are separated by a separation length L. As shown in FIG. The separation length L is defined by the length along the second surface 16n of the cylindrical portion 16d, for example, the arc-shaped length.

As shown in FIG. 11, in the external terminal 16, the first external connection portion 16a and the second external connection portion 16b are connected by a connecting portion 16f. At the same time, by bending the lid portion 16i of the first external connection portion 16a at the connecting portion 16f, the lid portion 16i of the first external connection portion 16a is closed. At this time, the upper surface of the contact protrusion 30 contacts the first surface 16m of the lid portion 16i. Therefore, the contact protrusion 30 that contacts the first surface 16m of the first external connection portion 16a and the second surface 16n of the second external connection portion 16b is disposed between the connecting portion 16f and the crimping engagement portion 16c. is set.

A gap 32 is formed between the first surface 16m and the second surface 16n and between the connecting portion 16f and the contact protrusion 30. As shown in FIG. The gap 32 has a separation length L and a height H, and has an arc shape when viewed from the insertion/removal direction (Z-axis direction).

The lid portion 16i of the first external connection portion 16a is closed and the crimping engagement portion 16c is crimped. Since the contact protrusion 30 is arranged between the first surface 16m and the second surface 16n, contact between the first surface 16m and the second surface 16n when the crimping engagement portion 16c is crimped is reduced. However, when viewed from the width direction (Y-axis direction) orthogonal to the insertion/removal direction (Z-axis direction), local contact occurs. Thus, even if the cover portion 16i is deformed by crimping the crimping engagement portion 16c, reliable contact can be obtained and the contact position can be defined uniquely. Therefore, by arranging the contact protrusion 30 at a position that does not resonate in the high frequency band used, it is possible to prevent electromagnetic resonance in the gap 32 and prevent occurrence of a resonance point in the insertion loss waveform in the high frequency band.

The separation length L of the gap 32 formed between the connecting portion 16 f and the contact protrusion 30 is dimensioned to be smaller than half the wavelength of the signal transmitted by the coaxial cable 40 . The separation length L of the gap 32 , that is, the position of the contact protrusion 30 can be adjusted so as to prevent electromagnetic resonance in the gap 32 . When the signal transmitted through the L-shaped coaxial connector 10 is in a high frequency band (for example, a millimeter wave band with a wavelength of 1 to 10 mm and a frequency band of 30 GHz to 300 GHz), the separation length L of the gap 32 is Dimensioned to be less than half the wavelength of the signal to be transmitted (eg, less than 0.5 mm to 5 mm). By adjusting the position of the contact protrusion 30 according to the wavelength of the signal transmitted in the L-shaped coaxial connector 10, the separation length L of the gap 32 is smaller than half the wavelength of the signal. In a wave-like high-frequency band, electromagnetic resonance in the gap 32 can be prevented, and occurrence of a resonance point in the insertion loss waveform can be prevented.

[Second embodiment]
The first external connection portion 16a of the external terminal 16 of the L-shaped coaxial connector 10 according to the second embodiment will be described with reference to FIG. FIG. 12 is a diagram illustrating the first external connection portion 16a of the external terminal 16 of the L-shaped coaxial connector 10 according to the second embodiment.

As shown in FIG. 12, the first external connection portion 16a of the external terminal 16 has, for example, two contact protrusions 30 on the first surface 16m of the lid portion 16i. The contact convex portion 30 is arranged so as to face the second surface 16n of the cylindrical portion 16d and the extension portion 16g. A contact protrusion 30 is provided between the connecting portion 16f and the crimping engagement portion 16c. In the example shown in FIG. 12, each contact protrusion 30 is arranged on the first surface 16m of the lid portion 16i at a position facing the second surface 16n of the cylindrical portion 16d. According to this configuration, since the contact protrusion 30 is positioned away from the crimping engagement portion 16c, reliable contact by the contact protrusion 30 can be obtained, and the contact position can be uniquely defined.

Each contact protrusion 30 has a rectangular shape when viewed from the width direction (Y-axis direction) orthogonal to the insertion/removal direction (Z-axis direction), and protrudes downward at a height H from the first surface 16m. In the circumferential direction of the first surface 16m of the lid portion 16i, the side end portion of the connecting portion 16f and the side end portion of the contact protrusion 30 are separated by a separation length L. As shown in FIG.

By bending the lid portion 16i of the first external connection portion 16a connected to the second external connection portion 16b at the connection portion 16f, the lid portion 16i of the first external connection portion 16a is closed. At this time, the lower surface of the contact protrusion 30 protruding downward comes into contact with the second surface 16n. Therefore, the contact protrusion 30 that contacts the first surface 16m of the first external connection portion 16a and the second surface 16n of the second external connection portion 16b is disposed between the connecting portion 16f and the crimping engagement portion 16c. is set.

A gap 32 is formed between the first surface 16m and the second surface 16n and between the connecting portion 16f and the contact protrusion 30 . The gap 32 has a separation length L and a height H, and has an arc shape when viewed from the insertion/removal direction (Z-axis direction).

By arranging the contact protrusion 30 on the first surface 16m of the lid portion 16i, the contact between the first surface 16m and the second surface 16n extends in the width direction orthogonal to the insertion/removal direction (Z-axis direction). When viewed from (Y-axis direction), local contact occurs. Thus, even if the cover portion 16i is deformed by crimping the crimping engagement portion 16c, reliable contact can be obtained and the contact position can be defined uniquely. Therefore, by arranging the contact protrusion 30 at a position that does not resonate in the high frequency band used, it is possible to prevent electromagnetic resonance in the gap 32 and prevent occurrence of a resonance point in the insertion loss waveform in the high frequency band.

[Third embodiment]
The second external connection portion 16b of the external terminal 16 of the L-shaped coaxial connector 10 according to the third embodiment will be described with reference to FIG. FIG. 13 is a diagram for explaining the second external connection portion 16b of the external terminal 16 of the L-shaped coaxial connector 10 according to the third embodiment.

As shown in FIG. 13, on the second surface 16n of the tubular portion 16d and the extension portion 16g, for example, two contact protrusions 30 (in FIG. 13, one contact protrusion disposed on the front side) Only the portion 30 is shown) are arranged in the circumferential direction. A contact protrusion 30 is provided between the connecting portion 16f and the crimping engagement portion 16c. Each contact protrusion 30 has a protruding curved surface, has an arc shape when viewed from the width direction (Y-axis direction) perpendicular to the insertion/removal direction (Z-axis direction), and is at a height H from the second surface 16n. protruding upwards. In the circumferential direction of the second surface 16n of the cylindrical portion 16d, the side end portion of the connecting portion 16f and the side end portion of the contact protrusion 30 are separated by a separation length L. As shown in FIG.

By bending the lid portion 16i of the first external connection portion 16a connected to the second external connection portion 16b at the connection portion 16f, the lid portion 16i of the first external connection portion 16a is closed. At this time, the contact protrusion 30 makes a point-like local contact with the first surface 16m when viewed from the width direction (Y-axis direction) orthogonal to the insertion/removal direction (Z-axis direction). Therefore, the contact protrusion 30 that contacts the first surface 16m of the first external connection portion 16a and the second surface 16n of the second external connection portion 16b is disposed between the connecting portion 16f and the crimping engagement portion 16c. is set.

A gap 32 is formed between the first surface 16m and the second surface 16n and between the connecting portion 16f and the contact protrusion 30 . The gap 32 has a separation length L and a height H, and has an arc shape when viewed from the insertion/removal direction (Z-axis direction).

By disposing the arc-shaped contact protrusions 30, the contact between the first surface 16m and the second surface 16n is shifted from the width direction (Y-axis direction) perpendicular to the insertion/removal direction (Z-axis direction). Look, it becomes a point-like local contact. As a result, even if the lid portion 16i is deformed by crimping the crimping engagement portion 16c, more reliable contact can be obtained and the contact position can be defined uniquely. Therefore, by arranging the contact protrusion 30 at a position that does not resonate in the high frequency band used, it is possible to prevent electromagnetic resonance in the gap 32 and prevent occurrence of a resonance point in the insertion loss waveform in the high frequency band.

[Fourth embodiment]
The second external connection portion 16b of the external terminal 16 of the L-shaped coaxial connector 10 according to the fourth embodiment will be described with reference to FIG. FIG. 14 is a diagram for explaining the second external connection portion 16b of the external terminal 16 of the L-shaped coaxial connector 10 according to the fourth embodiment.

As shown in FIG. 14, on the second surface 16n of the cylindrical portion 16d and the extension portion 16g, for example, four contact protrusions 30 (in FIG. 14, two contact protrusions arranged on the front side) are provided. Only the portion 30 is shown) are arranged in the circumferential direction. A plurality of contact projections 30 are arranged between the connecting portion 16f and the crimping engagement portion 16c. The contact protrusion 30 on the connecting portion 16f side has a rectangular shape when viewed from the width direction (Y-axis direction) orthogonal to the insertion/removal direction (Z-axis direction), and is above the second surface 16n at a first height H1. protrudes to In the circumferential direction of the second surface 16n of the tubular portion 16d, the side end portion of the connecting portion 16f and the side end portion of the contact protrusion 30 on the side of the connecting portion 16f are separated by a first separation length L1. there is The contact convex portion 30 on the side of the caulking guide portion 16p has a rectangular shape when viewed from the width direction (Y-axis direction) orthogonal to the insertion/removal direction (Z-axis direction), and is at a second height H2 from the second surface 16n. protruding upwards.

In the circumferential direction of the second surface 16n of the cylindrical portion 16d, a second separation is provided between the side end portion of the contact protrusion 30 on the connecting portion 16f side and the side end portion of the contact protrusion portion 30 on the crimping guide portion 16p side. They are separated by a gap 32 having a length L2. For example, the second separation length L2 is sized to be less than half the wavelength of the signal transmitted by the coaxial cable 40 . That is, the second separation length (the separation length between adjacent contact protrusions 30) L2 is smaller than half the wavelength of the signal transmitted by coaxial cable 40. FIG. When the band of the signal transmitted in the L-shaped coaxial connector 10 is, for example, a millimeter wave band with a wavelength of 1 to 10 mm and a frequency band of 30 GHz to 300 GHz, the second separation length L2 is transmitted Dimensioned to be less than half the wavelength of the signal (eg, less than 0.5 mm to 5 mm). According to the wavelength of the signal transmitted in the L-shaped coaxial connector 10, the contact is made so that the second separation length (the separation length between adjacent contact protrusions 30) L2 is less than half the wavelength of the signal. By adjusting the position of the convex portion 30, it is possible to prevent electromagnetic resonance in the gap 32 in a high frequency band such as millimeter waves, and to prevent occurrence of a resonance point in the insertion loss waveform.

The first height H1 of the contact projection 30 on the side of the connecting portion 16f is dimensioned to be higher than or equal to the second height H2 of the contact projection 30 on the caulking guide portion 16p (H1≧H2). It is That is, the heights of the plurality of contact projections 30 gradually decrease from the connecting portion 16f toward the crimping engagement portion 16c or are dimensionally configured to be the same. According to this configuration, when the lid portion 16i of the first external connection portion 16a is closed, reliable contact is obtained by the plurality of contact protrusions 30, and the contact position can be uniquely defined.

By bending the lid portion 16i of the first external connection portion 16a connected to the second external connection portion 16b at the connection portion 16f, the lid portion 16i of the first external connection portion 16a is closed. At this time, the contact convex portion 30 on the connecting portion 16f side and the contact convex portion 30 on the caulking guide portion 16p side respectively come into local contact with the first surface 16m. Therefore, the plurality of contact protrusions 30 that contact the first surface 16m of the first external connection portion 16a and the second surface 16n of the second external connection portion 16b at a plurality of points are connected to the connecting portion 16f and the crimping engagement portion 16c. is arranged between

Between the first surface 16m and the second surface 16n and between the connection portion 16f and the contact protrusion 30 on the connection portion 16f side, there is a gap 32 on the connection portion 16f side (the connection portion 16f and the contact protrusion 30 A gap 32) formed by is formed. The gap 32 on the connecting portion 16f side has a first spacing length L1 and a first height H1, and has an arc shape when viewed from the insertion/removal direction (Z-axis direction). A gap 32 ( A gap 32 is formed between adjacent contact protrusions 30 . The gap 32 on the caulking guide portion 16p side has a second separation length (a separation length between the contact protrusions 30) L2 and a second height H2, and has an arc shape when viewed from the insertion/extraction direction (Z-axis direction). doing

By disposing the plurality of contact protrusions 30, the contact between the first surface 16m and the second surface 16n is minimized when viewed from the width direction (Y-axis direction) orthogonal to the insertion/removal direction (Z-axis direction). resulting in multiple localized contacts. As a result, even if the lid portion 16i is deformed by crimping the crimping engagement portion 16c, more reliable contact can be obtained and the contact position can be defined uniquely. Therefore, by arranging the contact protrusion 30 at a position that does not resonate in the high frequency band used, it is possible to prevent electromagnetic resonance in the gap 32 and prevent occurrence of a resonance point in the insertion loss waveform in the high frequency band. Since the first separation length L1 and the second separation length (the separation length between the contact protrusions 30) L2 in the fourth embodiment are each shorter than the separation length L in the first embodiment, The frequency at which the resonance point occurs in the insertion loss waveform can be shifted to the high frequency side. This can prevent occurrence of a resonance point in the insertion loss waveform in the high frequency band used.

Although specific embodiments of the present invention have been described, the present invention is not limited to the above embodiments, and various modifications can be made within the scope of the present invention.

The contact protrusion 30 can be arranged on at least one of the first surface 16m and the second surface 16n. That is, in the above embodiment, the contact protrusions 30 are arranged on the first surface 16m or the second surface 16n, but they are arranged on both the first surface 16m and the second surface 16n. can also

The contact protrusion 30 can have various shapes such as a hemispherical shape, a cylindrical shape, a conical shape, a pyramid shape, a truncated cone shape, a truncated pyramid shape and a knife edge shape.

In the above embodiment, the contact protrusion 30 is arranged on the cylindrical portion 16d side, but the contact protrusion 30 is provided on at least one of the first surface 16m and the second surface 16n corresponding to the extension portion 16g. can be placed in

The present invention and embodiments are summarized as follows.

A coaxial connector 10 according to one aspect of the present invention includes:
an internal terminal 14 connected to the center conductor 42 of the coaxial cable 40;
A first external connection portion 16a connected to the external conductor 41 of the coaxial cable 40, a second external connection portion 16b arranged to surround the internal terminal 14, the first external connection portion 16a and the second external connection portion 16b. 2 an external terminal 16 having a connection portion 16f that connects the external connection portions 16b;
A coaxial connector 10 comprising an insulating member 12 disposed between the internal terminal 14 and the external terminal 16,
The second external connection portion 16b has a tubular portion 16d and an extension portion 16g,
The first external connection portion 16a includes a lid portion 16i configured to cover the cylindrical portion 16d and the extension portion 16g when viewed from the insertion/removal direction, and a lid portion 16i that is bent and crimped so as to cover the extension portion 16g. It has a crimping engagement portion 16c for
A contact convex portion 30 for contacting the first surface 16m of the lid portion 16i and the second surface 16n of the second external connection portion 16b facing the first surface 16m is connected to the connecting portion 16f and the crimping engagement portion 16c. It is characterized by being arranged between.

According to the above configuration, the contact convex portion 30 provided between the connecting portion 16f and the crimping engagement portion 16c ensures reliable contact between the lid portion 16i and the second external connection portion 16b. can uniquely define the contact position. Therefore, by arranging the contact protrusion 30 at a position that does not resonate in the high frequency band used, it is possible to prevent electromagnetic resonance in the high frequency band and to prevent occurrence of a resonance point in the insertion loss waveform.

Further, in the coaxial connector 10 of one embodiment,
The contact convex portion 30 is arranged on the first surface 16m facing the cylindrical portion 16d.

According to the above-described embodiment, since the contact projection 30 is positioned apart from the crimping engagement portion 16c, reliable contact by the contact projection 30 can be obtained, and the contact position can be uniquely defined.

Further, in the coaxial connector 10 of one embodiment,
The contact protrusion 30 is arranged on the second surface 16n.

According to the above embodiment, the contact protrusions 30 can be easily formed.

Further, in the coaxial connector 10 of one embodiment,
The contact convex portion 30 is arranged on the cylindrical portion 16d.

According to the above-described embodiment, since the contact projection 30 is positioned apart from the crimping engagement portion 16c, reliable contact by the contact projection 30 can be obtained, and the contact position can be uniquely defined.

Further, in the coaxial connector 10 of one embodiment,
A separation length L between the contact protrusion 30 and the connecting portion 16f is smaller than half the wavelength of the signal transmitted by the coaxial cable 40. As shown in FIG.

According to the above embodiment, it is possible to prevent electromagnetic resonance in the gap 32 formed between the contact protrusion 30 and the connecting portion 16f, and prevent occurrence of a resonance point in the insertion loss waveform.

Further, in the coaxial connector 10 of one embodiment,
A plurality of contact protrusions 30 are arranged between the connecting portion 16f and the caulking engagement portion 16c, and the distance L2 between adjacent contact protrusions 30 is determined by the coaxial cable 40. Less than half the wavelength of the transmitted signal.

According to the above embodiment, it is possible to prevent electromagnetic resonance in the gap 32 formed between the adjacent contact protrusions 30, and prevent occurrence of resonance points in the insertion loss waveform.

Further, in the coaxial connector 10 of one embodiment,
The heights of the plurality of contact projections 30 gradually decrease from the connecting portion 16f toward the crimping engagement portion 16c or remain the same.

According to the above embodiment, when the lid portion 16i of the first external connection portion 16a is closed, reliable contact is obtained by the plurality of contact protrusions 30, and the contact position can be uniquely defined.

Further, in the coaxial connector 10 of one embodiment,
The contact protrusion 30 has an arc shape.

According to the above embodiment, the contact by the contact projection 30 is a point-like local contact, so even if the lid portion 16i is deformed by crimping the crimping engagement portion 16c, more reliable contact can be obtained. In addition, the contact position can be uniquely defined.

A coaxial connector set 1 according to one aspect of the present invention includes:
The coaxial connector 10 described above and a mating connector 20 fitted to the coaxial connector 10 are provided.

According to the above configuration, the contact convex portion 30 provided between the connecting portion 16f and the crimping engagement portion 16c ensures reliable contact between the lid portion 16i and the second external connection portion 16b. can uniquely define the contact position. Therefore, by arranging the contact protrusion 30 at a position that does not resonate in the high frequency band used, it is possible to prevent electromagnetic resonance in the high frequency band and to prevent occurrence of a resonance point in the insertion loss waveform.

1... Coaxial connector set 10... L-shaped coaxial connector (coaxial connector)
DESCRIPTION OF SYMBOLS 12... Insulating member 12a... Internal holding part 12b... Center conductor holding part 14... Internal terminal 14a... Internal contact part 16... External terminal 16a... First external connection part 16b... Second external connection part 16c... Crimping engagement part 16d Cylindrical portion 16e Retaining portion 16f Connecting portion 16g Extension portion 16h Fitting convex portion 16i Lid portion 16k Bent portion 16m First surface 16n Second surface 16p Crimping guide portion 16s External conductor crimped portion 16t External coating crimped portion 17 Positioning portion 20 Opposite connector 22 Opponent insulating member 24 Opponent internal terminal 24a Opponent internal contact portion 24b Opponent internal mounting portion 26 Opponent external terminal 26a Opponent external Mounting portion 26b Counterpart second external connection portion 26h Fitting concave portion 30 Contact convex portion 32 Gap 40 Coaxial cable 41 Outer conductor 42 Center conductor 43 Outer covering H Height H1 First height H2 …Second height L …Separation length L1 …First separation length L2 …Second separation length (separation length between contact protrusions)

Claims (8)

an inner terminal connected to the center conductor of the coaxial cable;
a first external connection portion connected to an external conductor of the coaxial cable; a second external connection portion disposed so as to surround the internal terminal; and connecting the first external connection portion and the second external connection portion. an external terminal having a connecting portion for
A coaxial connector comprising an insulating member arranged between the internal terminal and the external terminal,
The second external connection portion has a tubular portion and an extension portion extending from the tubular portion,
The first external connection portion includes a lid portion configured to cover the cylindrical portion and the extension portion when viewed from the insertion/removal direction, and a crimping engagement for bending and crimping the extension portion so as to cover the extension portion. and
The lid portion has a first surface and the second external connection portion has a second surface facing the first surface,
A contact protrusion is provided on at least one of the first surface and the second surface,
the contact protrusion protrudes in the insertion/removal direction from at least one of the first surface and the second surface so as to bring the first surface and the second surface into contact;
the tubular portion has a notch on the second surface that is arranged following the connecting portion along the circumferential direction in which the second surface extends;
A gap spaced apart in the insertion/removal direction between the first surface and the second surface is formed between the notch and the contact protrusion,
The coaxial connector, wherein the contact protrusion is positioned away from the notch toward the crimping engagement portion . 2. The coaxial connector according to claim 1 , wherein said contact protrusion is arranged on said first surface facing said tubular portion. 3. The coaxial connector according to claim 1, wherein said contact protrusion is arranged on said second surface of said tubular portion . 4. The coaxial connector according to any one of claims 1 to 3 , wherein a distance between said contact protrusion and said connecting portion is smaller than half the wavelength of a signal transmitted by said coaxial cable. . A plurality of contact protrusions are provided between the connecting portion and the caulking engagement portion, and the distance between the adjacent contact protrusions corresponds to the wavelength of the signal transmitted by the coaxial cable. 4. A coaxial connector according to any one of claims 1 to 3 , which is less than half of the . 6. The coaxial connector according to claim 5 , wherein the heights of the plurality of contact protrusions gradually decrease or remain the same from the connecting portion toward the crimping engagement portion. 7. The coaxial connector according to any one of claims 1 to 6 , wherein the contact protrusion has a protruding curved surface. A coaxial connector set, comprising: the coaxial connector according to any one of claims 1 to 7 ; and a mating connector fitted to the coaxial connector.

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