The present invention relates to a multiple coaxial connector.
Japanese Patent Application Laid Open No. 2012-221797 is a conventional example of a connector that is formed by inserting a plurality of cables into one housing.
It is hard to manually insert a plurality of shell assemblies, which include a shell, a body, a contact, and a coaxial cable, into a housing at the same time and fix the shell assemblies in a manner to keep a positional relation of the shell assemblies matched.
An object of the present invention is to provide a multiple coaxial connector that realizes simple and secure fixation of shell assemblies to a housing.
A multiple coaxial connector according to the present invention includes a shell assembly, a housing, and a retainer.
The shell assembly includes a shell including a depression and a flange which go around a circumference of the shell, a body that is accommodated in the shell, a contact that is accommodated in the body, and a coaxial cable that is connected with the shell and the contact.
The shell assemblies are arranged in N rows in a second direction, the second direction being orthogonal to a first direction that is an extension direction of the shell assembly, and M columns in a third direction that is orthogonal to both of the first direction and the second direction, and the shell assemblies are fixed to the housing. Here, N and M are integers that are 2 or greater.
The housing includes: N×M pieces of insertion holes into which respective ends of the shell assemblies are inserted; an engagement portion that is formed on an inner surface of each of the insertion holes on a position, which is closer to an obliquely-adjacent insertion hole of the insertion holes, and is engaged with the depression; and a slit that is formed by cutting the housing in a direction orthogonal to an extension direction of the insertion holes, communicates with the insertion holes, and includes a first groove and a second groove formed on an inner surface of the slit in an order of longer distance from a center of the housing.
The retainer includes: a claw that is engaged with the first groove and the second groove when the retainer is inserted into the slit; and N pieces of concave portions that do not disturb movement of the shell and the flange in the insertion holes in a temporarily-fixed state in which the claw is engaged with the first groove, and of which each side surface abuts on the flange through insertion of the shell assembly in a fixed state in which the claw is engaged with the second groove.
According to the multiple coaxial connector of the present invention, shell assemblies can be simply and securely fixed to a housing.
An embodiment according to the present invention will be described in detail below. Here, components mutually having the same functions will be provided with the same reference numerals and the duplicate description thereof will be omitted.
A structure of a multiple coaxial connector according to a first embodiment will be described with reference to
As illustrated in
<Shell assembly 1>
The shell assemblies 1 are arranged in N rows (N is an integer which is 2 or greater) in a second direction (see “2” in bold typeface in
<Housing 2>
A structure of the housing 2 will be described in detail with reference to
The engagement portion 211 can be realized by a resin spring, for example. In the present embodiment, the engagement portion 211 once elastically deforms in an outside direction of the housing 2 when the shell 11 is pressed into the insertion hole 21. Then, the protrusion portion 2111 of the engagement portion 211 falls into the depression 111 and the engagement portion 211 elastically returns in an inside direction of the housing 2. An abutment surface 22A of the housing 2 abuts on the flange 112 at the same time with or immediately after the elastic return. Positioning between the housing 2 and the shell assembly 1 is thus performed (
However, it cannot be said that the shell assemblies 1 are sufficiently locked at this stage especially with respect to a force in a pulling-out direction. Accordingly, fixation with the retainers 3 described later is performed. The housing 2 includes slits 22B that are formed by cutting the housing 2 in a direction orthogonal to the extension direction of the insertion hole 21, as illustrated in
<Retainer 3>
In the present embodiment, two retainers 3 are respectively inserted into two slits 22B. The retainer 3 includes claws 31 that are engaged with the first grooves 221 and the second grooves 222 when the retainer 3 is inserted into the slit 22B, and N pieces (two pieces in the present embodiment) of concave portions 32, as illustrated in
The concave portions 32 are formed so that the concave portions 32 do not disturb movement of the shells 11 and flanges 112 in the insertion holes 21 in a temporarily-fixed state in which the claws 31 are engaged with the first grooves 221, and formed so that side surfaces of the concave portions 32 abut on the flanges 112 through insertion of the shell assemblies 1 in a fixed state in which the claws 31 are engaged with the second grooves 222.
When the side surface of the concave portion 32 is formed in a shape abutting on the flange 112 by a half or greater length of the circumference of the flange 112, the shell assemblies 1 can be more firmly fixed to the housing 2, thus being preferable.
<Advantageous effect: Engagement Portion 211>
The engagement portions 211 (resin springs) of the multiple coaxial connector according to the present embodiment are formed on the inner surfaces of respective insertion holes 21 on the positions that are closer to obliquely-adjacent insertion holes 21, that is, formed closer to the center of the connector. Accordingly, the outer shape of the connector can be downsized.
Since each of the engagement portions 211 (resin springs) of the multiple coaxial connector according to the present embodiment is formed closer to the center of the multiple coaxial connector, the engagement portions 211 can be formed in the same shape as each other. All of the engagement portions 211 (resin springs) have the same shapes as each other, being expected to simplify a design considering a spring property, simplify a mold design, and reduce maintenance cost as core parts can be shared through mold maintenance.
As described above, each of the engagement portions 211 of the multiple coaxial connector according to the present embodiment is arranged closer to the center of the housing 2. This structure equalizes material filling time from a gate position to the engagement portions 211 (resin springs) in housing molding and thus provides an advantageous effect that molding condition management for preventing short shot becomes easy, for example.
<Advantageous Effect: Engagement Portion 211=Half-Locked State>
The insertion holes 21 corresponding to respective shell assemblies 1 are predetermined, but the shell assemblies 1 may be inserted into wrong insertion holes 21. In this case, if the engagement portions 211 are engaged with the shells 11 in a fully-locked state, a special jig for displacing the engagement portions 211 is required to pull out the shells 11 from the housing 2. The pulling-out work using a special jig is affected by the length and own weight of a cable, largely deteriorating workability. Further, there is a possibility that the engagement portions 211 are damaged depending on the own weight of the cable. When the engagement portions 211 are engaged with the shells 11 in a half-locked state, the shells 11 can be pulled out from the housing 2 without damaging the engagement portions 211, making reworking in a case of miswiring easy.
<Advantageous Effect: Retainer 3>
The protrusion portion 2111 which is engaged with the depression 111 cannot be enlarged because of the structure and therefore, an area of the engagement portion 211 abutting on the shell 11 is small. This brings a structural problem that the protrusion portion 2111 is damaged and the shell assembly 1 falls out of the housing 2 when a load is applied to the shell assembly 1 in a pulling-out direction. On the other hand, the shell assemblies 1 directly abut on the retainers 3 and are completely fixed to the housing 2 and therefore, a pulling-out bearing force can be controlled without depending on the engagement portions 211 in the completely-fixed state.
When the structure is employed in which the retainers 3 abut on the flanges 112 of the shells 11 as described above, the abutting area on the flanges 112 can be made larger than an abutting area of the protrusion portions 2111 of the engagement portions 211. This structure makes it easy to realize and maintain a required pulling-out bearing force of the shell assemblies 1.
As illustrated in
Since the retainers 3 can be temporarily fixed on the housing 2, the retainers 3 can be provided in a temporarily-assembled state when providing the retainers 3 to a user as service parts. Thus, there are advantageous effects for facilitating inventory management and improving workability.
Even though man-hour is increased because of the addition of the process for temporarily assembling the retainers 3, workability deterioration caused by the own weight of the coaxial cable 14 can be prevented and a process after insertion of the shell assemblies 1 can be simplified, being able to shorten total working time.
A jig for the process of completely fixing the retainers 3 can be also simplified (manual assembly without using any jig is possible).
Since the retainers 3 are provided as a pair and are inserted in respective slits 22B as described above, the abutting area between the retainers 3 and the flanges 112 of the shells 11 can be enlarged and the pulling-out bearing force is improved.
<Modification>
The first embodiment discloses the example of N=2 and M=2. However, similar advantageous effects can be obtained even when the shell assemblies 1 and the insertion holes 21 are arranged, for example, in two rows and three columns or three rows and three columns.
The foregoing description of the embodiment of the invention has been presented for the purpose of illustration and description. It is not intended to be exhaustive and to limit the invention to the precise form disclosed. Modifications or variations are possible in light of the above teaching. The embodiment was chosen and described to provide the best illustration of the principles of the invention and its practical application, and to enable one of ordinary skill in the art to utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the invention as determined by the appended claims when interpreted in accordance with the breadth to which they are fairly, legally, and equitably entitled.
Number | Date | Country | Kind |
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2021-092422 | Jun 2021 | JP | national |