Patent Grant
10601153
This application claims priority from Japanese Patent Application No. 2017-118505 filed with the Japan Patent Office on Jun. 16, 2017, the entire content of which is hereby incorporated by reference.
The present disclosure relates to a coaxial connector assembly.
A coaxial connector includes a coaxial terminal having a center terminal connected to a core wire of a coaxial cable and an external terminal connected to a shield wire of the coaxial cable and surrounding the center terminal. It has been demanded for the coaxial terminal to suppress electromagnetic leakage from the external terminal to the center terminal. In addition, it has been demanded that a distance between the center terminal and the external terminal is set such that a specific impedance is generated at any position of a fitting portion in a connector fitting state, considering a permittivity between the center terminal and the external terminal.
Japanese Patent No. 3011671 proposes, for ensuring such impedance properties, a specific impedance (1/ve)×log(D/d) at an optional position in an axial direction range of an effective fitting length upon contact between center terminals and between external terminals in a fitting state between a plug connector and a receptacle connector is set constant when the outer diameter of the center terminal is d, the inner diameter of the external terminal is D, and a permittivity between the center terminal and the external terminal is e. A coaxial connector assembly of Japanese Patent No. 3011671 is based on an assumption that the plug connector (a plug) and the receptacle connector (a jack) employs a one-touch slide-in (snap-in) technique. According to Japanese Patent No. 3011671, when both connectors are in a predetermined fitting state in an axial direction as a connector fitting direction, if both connectors move, in the axial direction, relative to each other by a clearance generated between the connectors in the axial direction, the above-described specific impedance can be maintained.
In the one-touch slide-in technique employed for the coaxial connector assembly of Japanese Patent No. 3011671, in a state in which both connectors form a single axis and connection between the center terminals and between external terminals is made, the tubular external terminals of both connectors are slidably fitted together in the axial direction as disclosed as, e.g., a snap-in technique in JP-UM-A-64-019277. In this manner, both connectors are locked at a predetermined fitting position. For such locking, an annular groove configured such that a sectional shape in a plane perpendicular to the axis is a V-shape is provided at one of tubular fitting surfaces of both external terminals, and an annular protrusion to be engaged with the annular groove is provided at the other fitting surface. Thus, when both external terminals slide relative to each other to the predetermined fitting position, the annular protrusion is locked in the annular groove. With this configuration, both connectors have the function of suppressing connector detachment.
A coaxial connector assembly according to the present disclosure include a plug connector and a receptacle connector each configured to hold, at a housing of an electric insulating material, a coaxial terminal including a center terminal of a coaxial cable and an external terminal surrounding the center terminal, wherein, at least one of the plug connector or the receptacle connector is a cable connector, the housing of the plug connector and the housing of the receptacle connector have an engageable/disengageable lock mechanism at a predetermined fitting position between the housings, in an engagement state, a range of relative movement between the coaxial terminals in an axial direction as a coaxial terminal insertion/detachment direction is smaller than a minimum effective fitting length, the minimum effective fitting length is a shorter one of a center terminal effective fitting length or an external terminal effective fitting length, the center terminal effective fitting length is a distance from a start position of contact between the center terminals at a start of fitting between the coaxial terminals to an end position of contact between the center terminals at an end of fitting between the coaxial terminals, the external terminal effective fitting length is a distance from a start position of contact between the external terminals at the start of fitting between the coaxial terminals to an end position of contact between the external terminals at the end of fitting between the coaxial terminals, and an impedance in the axial direction range of the minimum effective fitting length is matched to a specific impedance.
In the following detailed description, for purpose of explanation, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. It will be apparent, however, that one or more embodiments may be practiced without these specific details. In other instances, well-known structures and devices are schematically shown in order to simplify the drawing.
In the above-described coaxial connector having the center terminal and the external terminal, measures to suppress detachment by the snap-in technique between the tubular external terminals are taken. However, the V-shaped annular protrusion and annular groove are locked together, and therefore, the annular protrusion and the annular groove run on each other along V-shaped inclined surfaces thereof and are detached from each other when unintended great external force acts in a detachment direction. Moreover, in JP-UM-A-64-019277, slits extending in the axial direction are, for snap-in fitting, formed at multiple circumferential positions of one of the external terminal. This allows elastic diameter expansion upon snap-in. Thus, there is a probability that electromagnetic leakage through the slits is caused. For this reason, a heat-shrinkable conductive tube is, as countermeasures, fitted onto two external terminals fitted together, thereby suppressing electromagnetic leakage through the slits as described above. In addition, suppression of detachment of the terminals on both sides is enhanced to a certain extent.
However, even in this technique, a heat shrinkage effect cannot be expected as long as the conductive tube is not a relatively-thin tube. Moreover, coupling strength in the axial direction is not sufficient. Further, it is demanded for the connectors that the external terminals can be disengaged, i.e., detached, from each other in an intended predetermined situation. In this state, the conductive tube needs to be broken. As a result, extreme inconvenience is caused in the case of repeating insertion/detachment of the connectors in an intended manner.
For these reasons, for full lock without relying on the external terminals upon connector coupling, a disengageable lock mechanism needs to be provided at the housings holding the external terminals. In a general connector lock mechanism, an elastic arm with a stop is provided at one of the housings, and another stop to be locked at the above-described stop is provided at the other housing. With this configuration, the elastic arm generates elastic deflection according to the principle of leverage upon connector fitting. The stop provided at the elastic arm moves over another stop of the partner connector, and then, these stops are locked together in the axial direction. This suppresses detachment of the housings from each other as long as disengagement force is applied to the elastic arm in an intended manner. This leads to so-called “full lock.”
However, when this full lock technique is employed for the coaxial connector, another problem is newly caused. For this full lock technique, locking using the stops and generation of elastic deflection by the elastic arm for unlocking are necessary. Thus, a clearance allowing relative movement between the housings in the axial direction within a limited range is provided such that no interference such as collision or friction is caused between the stops upon locking or unlocking. In a case where at least one of two connectors fitted together is a cable connector, when the external force of pulling the cable acts on the cable, both connectors move relative to each other in the above-described clearance. Thus, there is a probability that the coaxial terminals of the coaxial connectors are shifted relative to each other in the axial direction in the connector fitting state by the sum of the above-described clearance and backlash in the axial direction upon assembly of the external terminal and the housing. Such shift might influence the above-described specific impedance.
In view of the above-described situation, the present disclosure is intended to maintain, in a coaxial connector assembly, a specific impedance while realizing deactivatable full lock.
A coaxial connector assembly according to an embodiment of the invention includes a plug connector and a receptacle connector each configured to hold, at a housing of an electric insulating material, a coaxial terminal including a center terminal of a coaxial cable and an external terminal surrounding the center terminal, wherein at least one of the plug connector or the receptacle connector is a cable connector.
The coaxial connector assembly, in the embodiment, the housing of the plug connector and the housing of the receptacle connector have an engageable/disengageable lock mechanism at a predetermined fitting position between the housings, in an engagement state, a range of relative movement between the coaxial terminals in an axial direction as a coaxial terminal insertion/detachment direction is smaller than a minimum effective fitting length, the minimum effective fitting length is a shorter one of a center terminal effective fitting length or an external terminal effective fitting length, the center terminal effective fitting length is a distance from a start position of contact between the center terminals at a start of fitting between the coaxial terminals to an end position of contact between the center terminals at an end of fitting between the coaxial terminals, the external terminal effective fitting length is a distance from a start position of contact between the external terminals at the start of fitting between the coaxial terminals to an end position of contact between the external terminals at the end of fitting between the coaxial terminals, and an impedance in the axial direction range of the minimum effective fitting length is matched to a specific impedance.
According to such a configuration, the housings of both connectors have the lock mechanism. Thus, the so-called “full lock” deactivatable only in an intended situation is realized. In addition, the impedance between the coaxial terminals of both connectors is matched to the specific impedance in the axial direction range of the minimum effective fitting length. Moreover, the range of relative movement between the coaxial terminals in the axial direction is smaller than the minimum effective length. Thus, even when both coaxial connectors move relative to each other in the above-described relative movement range in the lock state, matching to the specific impedance as described above is ensured.
In the embodiment, the external terminal of the coaxial terminal in one connector of the plug connector or the receptacle connector has a first external contact portion, the first external contact portion has a smaller diameter than a diameter of the external terminal in an axial area of the external terminal corresponding to a center contact portion of the center terminal, and extends toward the coaxial terminal in the other connector of the plug connector or the receptacle connector from the corresponding area, the external terminal of the coaxial terminal of the other connector has a second external contact portion, the other contact portion has a smaller diameter than a diameter of an exterior base portion fitted onto a dielectric body, and extends to a middle position of the center terminal in the axial direction, and the center terminal of the coaxial terminal of the other connector is formed such that a diameter of the center contact portion protruding toward the coaxial terminal of the one connector with respect to the external terminal in the axial direction is greater than a diameter of a portion surrounded by the external contact portion of the coaxial terminal of the other connector.
With such a configuration, matching to the specific impedance in the axial direction range of the minimum effective fitting length can be realized.
In the embodiment, the range of relative movement between the coaxial terminals is a sum of a clearance between the housings in the axial direction in a connector lock state and backlash in the axial direction between each housing and the corresponding external terminal.
With such a configuration, matching to the specific impedance is ensured even when the coaxial terminals move relative to each other in the axial direction in the lock state, considering an axial-direction clearance necessary for the lock mechanism and backlash inevitably generated between the housing and the external terminal of each connector.
In the present embodiment, the plug connector and the receptacle connector can be configured such that multiple coaxial terminals are housed. With this configuration, the housings of both connectors are fitted together such that multiple coaxial terminals are fitted and connected together at a time.
In the present embodiment, wherein the receptacle connector has a metal shield shell in the housing of the receptacle connector, the center terminal includes multiple center terminals, the dielectric body includes multiple dielectric bodies, and the external terminal includes multiple external terminals, the shield shell is formed to collectively house the center terminals, the dielectric bodies, and external terminals, and the shield shell is configured such that a connector fitting side portion thereof enters, in a fitting state between the receptacle connector and the plug connector, the housing of the plug connector to contact the external terminal of the plug connector.
In such a configuration, the shield shell can collectively shield multiple coaxial terminals. In this state, the single shield shell is preferably formed such that the coaxial terminals are separated from each other to be shielded respectively. For example, the shield shell may include a support tubular portion surrounding and supporting each external terminal of the receptacle connector in a separated state.
In the present embodiment, the plug connector may have a retainer configured to determine the position of each coaxial terminal. This leads to a constant distance between the coaxial terminals.
In the present embodiment, the housings of the coaxial connectors are, as described above, provided with the lock mechanism for deactivatable full lock. Moreover, in the fitting state necessary for full lock, the range of relative movement between the coaxial terminals in the axial direction is set smaller than the minimum effective fitting length as a shorter one of the center terminal effective fitting length or the external terminal effective fitting length. Further, in the axial direction range of the minimum effective fitting length, the impedance is matched to the specific impedance. Thus, full lock is ensured. In addition, even when the connectors in the fitting state move in the axial direction due to the clearance and the backlash as described above, the specific impedance is not influenced at all.
Hereinafter, a coaxial connector assembly as one embodiment of the present disclosure will be described with reference to the attached drawings.
In
In the state of
The coaxial terminal 20 is attached to the coaxial cable 11. As seen from
The center terminal 21 is obtained in such a manner that a metal band-shaped body is formed in a stepped substantially-cylindrical shape having a center axis along a longitudinal direction thereof and joining is performed for the formed metal band-shaped body. In
The center connection portion 21B is connected to the core wire 13 by, for example, solder connection or pressure bonding.
As in the center terminal 21, the external terminal 22 is formed in such a manner that a metal band-shaped plate is shaped in a substantially cylindrical shape having a center axis along a longitudinal direction thereof. As seen from
The external terminal 22 has, in the axial direction, the following position relationship with each portion 22A to 22E of the external terminal 22, each portion 21A to 21C of the center terminal 21, the dielectric body 23, and each portion 13 to 16 of the coaxial cable 11. Such a position relationship will be also described below with reference to
First, the external connection portion 22A is inserted between the dielectric body 14 and the exposed shield wire 15 of the coaxial cable 11, and is positioned in an exposed area of the shield wire 15 in the axial direction.
The back large diameter portion 22D is, in the axial direction, positioned in an area between a front end position of the dielectric body 14 of the coaxial cable 11 and a back end position of the dielectric body 23 attached to the narrow diameter portion 21A of the center terminal 21. Such an area is substantially equal to exposed areas of the core wire 13 and the center connection portion 21B.
The position determination portion 22B is, in the axial direction, positioned in the area of the dielectric body 23 attached to the center terminal 21. The position determination portion 22B forms an annular groove portion between the back large diameter portion 22D and the front large diameter portion 22E positioned in the front and back of the position determination portion 22B. Each of later-described retainers enters, from the circumferential direction (a tangential direction), toward the position determination portion 22B forming the annular groove portion, thereby determining the position of the external terminal 22 in the radial direction and the axial direction. As described above, the position determination portion 22B has the function of holding the position thereof.
The front large diameter portion 22E is, in the axial direction, positioned in the area of the center contact portion 21C of the center terminal 21. That is, the front large diameter portion 22E extends across an area from a front end position of the dielectric body 23 attached to the center terminal 21 to a front end position of the center contact portion 21C.
As seen from
As seen from
Meanwhile, the back fastening arm portion 24B is formed in a cylindrical shape in such a manner that the back fastening arm portion 24B is directly swaged to the outer coat 16 of the coaxial cable 11. In this manner, the external terminal 22 is firmly held in connection with the coaxial cable 11 by the metal fastener 24 (see
As described above, the coaxial terminal 20 of the plug connector I attached to the coaxial cable 11, i.e., the center terminal 21 and the external terminal 22, ensures a specific impedance with respect to a coaxial terminal of the receptacle connector II with the plug connector I being fitted and connected to the later-described receptacle connector II. Such a specific impedance will be described again after description of the receptacle connector II.
In the coaxial terminal equipped cable 10 in a state in which the coaxial terminal 20 of the plug connector I is attached to the coaxial cable 11, the coaxial terminal 20 is housed in the housing 30 made of the electric insulating material, and is held at a predetermined position. In the housing 30 illustrated in
The housing 30 is in a rectangular tubular shape with a substantially rectangular parallelepiped outer shape, the rectangular tubular shape having a substantially square sectional shape perpendicular to the axial direction such that each axes of four coaxial terminal equipped cables 10 parallel with each other are arranged in two tiers and two rows. As seen from
In the tubular support portion 31, the external terminal 22 of the coaxial terminal equipped cable 10 is positioned on a center line of each partial cylinder surface of the receiving inner surface 31B.
The housing 30 of the plug connector I has a lock arm 32 standing at a front end position of an upper outer surface of the tubular support portion 31 and extending backward. The lock arm 32 forms a lock mechanism in combination with a corresponding portion of the receptacle connector II. An inverted U-shaped protection frame 33 is provided at a middle position of an upper outer surface of the housing 30 in the axial direction. The lock arm 32 penetrates an internal space of the protection frame 33, and extends to a position (the left side as viewed in
The position determination portion 22B is provided, as the annular groove portion, at the external terminal 22 of the housing 30 in a middle position in the axial direction, as shown in
A lower surface of the upper retaining piece 34B, an upper surface of the lower retaining piece 34D, and both of upper and lower surfaces of the middle retaining piece 34C each have arc surface portions contactable with the outer peripheries of the position determination portions 22B of the external terminals 22. The retainer 34 has a locking protrusion 34B-1 on an upper surface of the upper retaining piece 34B, and has a locking protrusion (not shown) 34D-1 at a lower surface of the lower retaining piece 34D. Moreover, the retainer 34 is locked at protrusions 35A, 35B provided at corresponding positions of the housing 30. Thus, the retainer 34 is less detachable. With this configuration, three retaining pieces 34B, 34C, 34D of each of the retainers 34 attached to the attachment windows 35 of the housing 30 from both sides thereof enter toward the position determination portions 22B of the external terminals 22 of the total of four coaxial terminal equipped cables 10 in two tiers and two rows, and are retained such that the external terminals 22 are held at specified positions in the axial direction and the upper-to-lower direction.
Next, in the receptacle connector II fitted and connected to the plug connector I, a coaxial terminal unit 50 is, at a coaxial terminal portion thereof, housed in the housing 60 made of an electric insulating material, as seen from
In the present embodiment, the body portions 51 of the coaxial terminal unit 50 form two types of body portions 51, 51′ each configured such that the center terminal 52 is formed integrally with a dielectric body 53. The body portions 51, 51′ have the same basic structure, except that the lengths of the dielectric body 53 and the center terminal 52 are different between the body portions 51, 51′. Thus, only one type of body portion 51 with a longer center terminal 52 and a longer dielectric body 53 will be described.
As seen from
Unlike the core wire 13, in the plug connector I, as the strand twisted wire, the center terminal 52 of the body portion 51 is, in the present embodiment, formed as a single core, and is bent in an L-shape as seen from
As seen from
Thus, the cylindrical portion 53B integrally hold the cylindrical portion 53A forming the dielectric body 53 and the center terminal 52, thereby forming the body portion 51. On the other hand, in another type of body portion 51′, the lengths of the horizontal and vertical portions of the center terminal 52, i.e., the length of a cylindrical portion 53′A of the dielectric body 53 and the length of a rectangular cylindrical portion 53′B of the dielectric body 53, are each shorter than the length of the cylindrical portion 53A and the length of the rectangular cylindrical portion 53B such that front and back end positions of the body portion 51′ are coincident with front and back end positions of the center terminal 52 when the body portion 51′ is arranged inside (inside a bent portion of a L-shape) of the L-shaped body portion 51.
The external terminal 55 is formed in a stepped cylindrical shape by spinning of a metal plate. A large diameter portion forming the back side as viewed in
The shield shell 56 housing coaxial terminal portions of the coaxial terminal unit 50 is formed in a case shape by forming a metal material. As seen from
The box-shaped portion 58 has a body portion 58A with a substantially cubic outer shape, and an attachment bottom portion 58B. The box-shaped portion 58 opens to the back and lower sides. The attachment bottom portion 58B slightly protrudes to both sides at a bottom portion of the body portion 58A. Such a bottom surface serves as an attachment surface for a circuit board (not shown) and the like. Moreover, attachment legs 58B-1 protruding downward are each provided at corner portions of the bottom portion. The attachment legs 58B-1 are each attached to corresponding holes of the circuit board by, e.g., soldering.
The box-shaped portion 58 is configured such that two types of shield plates 59A, 59B are attached to the box-shaped portion 58 from below. As illustrated in
As seen from
In the front tubular portion 61, a space where the tubular support portion 57 of the shield shell 56 is housed from the back of the front tubular portion 61 is formed. In addition, the front tubular portion 61 has an upper groove wall 63 protruding from an upper wall of the front tubular portion 61 such that a space where the lock arm 32 provided at the housing 30 of the plug connector I is received from the front of the front tubular portion 61 is formed. The upper groove wall 63 extends backward to a middle position of the back tubular portion 62 in the axial direction. A locking portion 63A is formed at a back edge (an edge at a position facing the plug connector I) portion of the upper groove wall 63. Moreover, a lock space 63B penetrating in the upper-to-lower direction is formed in the back of the locking portion 63A. Side portions 63B-1 positioned on both sides of the lock space 63B guide the lock arm 32 back and forth along side surfaces thereof. Two slits 62A are formed at each side surface of the back tubular portion 62. The slits 62A extend to a back end of the back tubular portion 62. An elastic piece 62B is formed between two slits 62A. A locking protrusion 62B-1 to be locked at a back edge of the box-shaped portion 58 of the shield shell 56 is provided on the inside of the back end of the elastic piece 62B (see
A back edge of the lock space 63B forms a stopper surface 63C. The stopper surface 63C restricts the amount of backward movement of the lock arm 32 relative to a front end of the lock arm 32. Thus, when the plug connector I is fitted in the receptacle connector II, the coaxial terminals 20 and the coaxial terminal unit 50 are fitted and connected together. Meanwhile, the tubular support portion 31 of the housing 30 of the plug connector I enters the front tubular portion 61 of the housing 60 of the receptacle connector II. In such an entrance process, the lock arm 32 intrudes a groove of the upper groove wall 63, and then, advances in the groove. The locking protrusion 32A at the front end of the lock arm 32 comes into contact with the locking portion 63A of the upper groove wall 63. Then, the inclined front surface of the locking protrusion 32A receives downward pressing force from the locking portion 63A, and the lock arm 32 generates downward elastic deflection. Then, the lock arm 32 further advances beyond the locking portion 63A. Immediately after the locking portion 63A has passed the position of the locking portion 63A, the above-described pressing force is released, and the lock arm 32 returns to a state before elastic deflection. A position at which the front end of the lock arm 32 contacts the stopper surface 63C is the most advanced position of the lock arm 32.
In the present embodiment, it is set such that a distance (the former) from the front end of the lock arm 32 of the plug connector I to a back end of the locking protrusion 32A provided at the lock arm 32 is shorter than a distance (the latter) from the stopper surface 63C of the receptacle connector II to a front surface of the locking portion 63A. That is, in the connector fitting state, even when the plug connector I and the receptacle connector II are in the fully-locked state, the housings 30, 60 can move relative to each other in a clearance corresponding to a difference between the former distance and the latter distance.
That is, such relative movement is movement from one of an advancing state of the plug connector I as seen from
Upon fitting connection among the coaxial terminals 20 and the coaxial terminal unit 50 of both connectors I, II, an axial distance (length) from a start position to an end position of contact between both connectors I, II is generally defined as an effective fitting length. That is, in the present embodiment, there are an effective fitting length between the center terminals 21, 52 and an effective fitting length between the external terminals 22, 55. A spacing between the center terminals 21, 52 is herein defined as a center terminal effective fitting length, and a spacing between the external terminals 22, 55 is herein defined as an external terminal effective fitting length. In the present embodiment, the above-described range of relative movement between the coaxial terminals is set smaller than the minimum effective fitting length as a shorter one of the center terminal effective fitting length or the external terminal effective fitting length.
In the present embodiment, the external terminal of the coaxial terminal in one connector of the plug connector I or the receptacle connector II has the external contact portion. Such an external contact portion has a smaller diameter than the diameter of the external terminal in an axial area of the external terminal corresponding to the center contact portion of the center terminal, and extends toward the coaxial terminal in the other connector of the plug connector I or the receptacle connector II from such a corresponding area. The external terminal of the coaxial terminal of the other connector also has the external contact portion. Such an external contact portion has a smaller diameter than the diameter of the exterior base portion fitted onto the dielectric body, and extends to a middle position of the center terminal in the axial direction. The center terminal of the coaxial terminal of the other connector is formed such that the diameter of the center contact portion protruding toward the coaxial terminal of the one connector with respect to the external terminal in the axial direction is greater than the diameter of the portion surrounded by the external contact portion of the coaxial terminal of the other connector. Thus, the impedance between the coaxial terminal 20 and the coaxial terminal unit 50 is, in the direction connector fitting state, matched to the already-described specific impedance in the axial range of the minimum effective fitting length.
Considering with reference to the state of
First, for the plug connector I, the center terminal 21 and the external terminal 22 are attached to the coaxial cable 11 illustrated in
As seen from
Next, for the receptacle connector II, two of each type of body portion 51, 51′, i.e., the total of four body portions 51, 51′, are assembled into the shield shell 56 from the back thereof. At this point, each center contact portion 54 is assembled in order to be positioned in each hole-shaped receiving portion 57A of the shield shell 56. In such an assembly state, the dielectric bodies 53, 53′ of the body portions 51, 51′ are positioned in the internal space of the box-shaped portion 58 as the back portion of the shield shell 56. Thereafter, each external terminal 55 is press-fitted in the receiving portions 57A of the shield shell 56 to surround each center contact portion 54. In this manner, the center contact portions 54 and the external terminals 55 form the coaxial terminal.
After the body portions 51, 51′ have been assembled into the shield shell 56, the shield plates 59A, 59B are attached to the shield shell 56 from below, and the rectangular cylindrical portions 53B, 53′B of the body portions 51, 51′ are shielded.
The housing 60 is attached to the shield shell 56 into which the coaxial terminal unit 50 is assembled as described above. The locking protrusions 62B-1 provided at a back end of the housing 60 are locked at the back edge of the shield shell 56. Thus, the housing 60 is less detached from the shield shell 56. In this manner, the receptacle connector II illustrated in
Upon usage of a connector connection, both housings 30, 60 of the plug connector I and the receptacle connector II are fitted together. In such fitting, the lock arm 32 of the plug connector I first enters the groove of the upper groove wall 63 provided at the housing 60 of the receptacle connector II. In this process, the locking protrusion 32A of the lock arm 32 receives the pressing force from the upper groove wall 63. Accordingly, the lock arm 32 generates elastic deflection. Eventually, the locking protrusion 32A passes the locking portion 63A. At this point, fitting connection between both connectors I, II is completed. That is, the coaxial terminals 20 of the plug connector I and the coaxial terminal unit 50 of the receptacle connector II are in a connection state. This realizes the fully-locked state for reducing detachment of both connectors I, II. Even in this fitting connection state, both connectors I, II have the already-described relative movement range. Thus, in response to external force, both connectors might move relative to each other in the axial direction within such a range. This means that there is a probability that the coaxial terminals 20 and the coaxial terminal unit 50 also move relative to each other in this range. However, in the present embodiment, the impedance between the coaxial terminals is matched to have the specific impedance in the above-described relative movement range. Thus, electric properties upon connector connection are not influenced at all.
The present embodiment is not limited to the embodiments illustrated in
The front end portion of the center terminal 52 forms the center contact portion 54 in such a manner that a band-shaped material is folded by bending from the front to the back. A back portion of the center terminal 52 with respect to the center contact portion 54 is folded by bending in a width direction (a direction perpendicular to the plane of paper of
The embodiment of
Further, in the above-described embodiment, at least one of the plug connector or the receptacle connector is a cable connector. Specifically, the above-described embodiment describes an example where the plug connector is the cable connector. However, the present disclosure is not limited to above, and the receptacle connector may be the cable connector. Alternatively, both connectors may be the cable connectors. For example, in a case where the illustrated receptacle connector II is the cable connector, the receptacle connector II has such a structure that a back portion of the external terminal 55 is combined with the front large diameter portion 22E of the external terminal 22 of the plug connector. The structure of the back tubular portion 62 of the housing 60 of the receptacle connector II is similar to a back structure of the plug connector I with respect to the retainers 34. That is, the cable connector employing the structure of the plug connector other than the fitting portion and the lock portion is realized.
The coaxial connector assembly of the present disclosure may be the following first to seventh coaxial connector assemblies.
The first coaxial connector assembly is a coaxial connector assembly including a plug connector and a receptacle connector each configured to hold, at a housing of an electric insulating material, a coaxial terminal including a center terminal of a coaxial cable and an external terminal surrounding the center terminal, at least one of the plug connector or the receptacle connector being a cable connector. In this coaxial connector assembly, the housing of the plug connector and the housing of the receptacle connector have a disengageable lock mechanism configured to engage at a predetermined fitting position between the housings to suppress detachment. In a lock state, the range of relative movement between the coaxial terminals in an axial direction as a coaxial terminal insertion/detachment direction is set smaller than the minimum effective fitting length as a shorter one of a center terminal effective fitting length or an external terminal effective fitting length defined as a distance from a start position of contact between the center terminals or the external terminals at the start of fitting between the coaxial terminals to an end position of contact at the end of fitting. The axial direction range of the minimum effective fitting length is matched to a specific impedance.
The second coaxial connector assembly is the first coaxial connector assembly in which the external terminal of the coaxial terminal in a one connector as one of the plug connector or the receptacle connector has an external contact portion having a smaller diameter than that in an axial area corresponding to a center contact portion of the center terminal and extending toward the coaxial terminal in a the other connector as the other one of the plug connector or the receptacle connector from the corresponding area, the external terminal of the coaxial terminal of the other connector has an external contact portion having a smaller diameter than that of an exterior base portion fitted onto a dielectric body and extending to a middle position of the center terminal in the axial direction, and the center terminal of the coaxial terminal of the other connector is formed such that the diameter of the center contact portion protruding toward the coaxial terminal of the one connector with respect to the external terminal in the axial direction is greater than that of a portion surrounded by the external contact portion of the coaxial terminal of the other connector.
The third coaxial connector assembly is the first or second coaxial connector assembly in which the range of relative movement between the coaxial terminals of the plug connector and the receptacle connector is a range determined by the sum of a clearance between the housings in the axial direction in both connector lock state and backlash in the axial direction between each housing and the corresponding external terminal thereof.
The fourth coaxial connector assembly is any one of the first to third coaxial connector assemblies in which the plug connector and the receptacle connector house multiple coaxial terminals.
The fifth coaxial connector assembly is any one of the first to fourth coaxial connector assemblies in which the receptacle connector has a metal shield shell in the housing of the receptacle connector, the shield shell is formed to collectively house multiple center terminals, multiple dielectric bodies, and multiple external terminals, and the shield shell is configured such that a connector fitting side portion thereof enters, in a fitting state between the receptacle connector and the plug connector, the housing of the plug connector to contact the external terminal of the plug connector.
The sixth coaxial connector assembly is the fifth coaxial connector assembly in which the shield shell has a support tubular portion surrounding and supporting each external terminal of the receptacle connector in a separated state.
The seventh coaxial connector assembly is any one of the first to fifth coaxial connector assemblies in which the plug connector has a retainer configured to determine the position of each coaxial terminal.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2017-118505 | Jun 2017 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4412717 | Monroe | Nov 1983 | A |
| 4598961 | Cohen | Jul 1986 | A |
| 4619496 | Forney, Jr. | Oct 1986 | A |
| 5842872 | Hosler, Sr. | Dec 1998 | A |
| 6045402 | Embo | Apr 2000 | A |
| 6386888 | Skopic | May 2002 | B1 |
| 6663397 | Lin | Dec 2003 | B1 |
| 7014503 | Wang | Mar 2006 | B1 |
| 7029286 | Hall | Apr 2006 | B2 |
| 7150648 | Hall | Dec 2006 | B1 |
| 8430675 | Hardy | Apr 2013 | B2 |
| 8932079 | Marsh | Jan 2015 | B2 |
| Number | Date | Country |
|---|---|---|
| 64019277 | Jan 1989 | JP |
| 3011671 | Feb 2000 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20180366843 A1 | Dec 2018 | US |
