EP3944422A1 - Connecteur enfichable, en particulier un connecteur enfichable automobile mini-coaxial, destiné à la connexion à un dispositif fiche compatible, ainsi que procédé de production d'un connecteur enfichable - Google Patents

Connecteur enfichable, en particulier un connecteur enfichable automobile mini-coaxial, destiné à la connexion à un dispositif fiche compatible, ainsi que procédé de production d'un connecteur enfichable Download PDF

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Publication number
EP3944422A1
EP3944422A1 EP21186911.0A EP21186911A EP3944422A1 EP 3944422 A1 EP3944422 A1 EP 3944422A1 EP 21186911 A EP21186911 A EP 21186911A EP 3944422 A1 EP3944422 A1 EP 3944422A1
Authority
EP
European Patent Office
Prior art keywords
housing body
connector
section
coax
contact
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP21186911.0A
Other languages
German (de)
English (en)
Inventor
Michael Quiter
Dirk Michel
Jaime Fernandez Serrano
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Yamaichi Electronics Deutschland GmbH
Original Assignee
Yamaichi Electronics Deutschland GmbH
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Yamaichi Electronics Deutschland GmbH filed Critical Yamaichi Electronics Deutschland GmbH
Publication of EP3944422A1 publication Critical patent/EP3944422A1/fr
Pending legal-status Critical Current

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R24/00Two-part coupling devices, or either of their cooperating parts, characterised by their overall structure
    • H01R24/38Two-part coupling devices, or either of their cooperating parts, characterised by their overall structure having concentrically or coaxially arranged contacts
    • H01R24/40Two-part coupling devices, or either of their cooperating parts, characterised by their overall structure having concentrically or coaxially arranged contacts specially adapted for high frequency
    • H01R24/50Two-part coupling devices, or either of their cooperating parts, characterised by their overall structure having concentrically or coaxially arranged contacts specially adapted for high frequency mounted on a PCB [Printed Circuit Board]
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R12/00Structural associations of a plurality of mutually-insulated electrical connecting elements, specially adapted for printed circuits, e.g. printed circuit boards [PCB], flat or ribbon cables, or like generally planar structures, e.g. terminal strips, terminal blocks; Coupling devices specially adapted for printed circuits, flat or ribbon cables, or like generally planar structures; Terminals specially adapted for contact with, or insertion into, printed circuits, flat or ribbon cables, or like generally planar structures
    • H01R12/50Fixed connections
    • H01R12/51Fixed connections for rigid printed circuits or like structures
    • H01R12/55Fixed connections for rigid printed circuits or like structures characterised by the terminals
    • H01R12/58Fixed connections for rigid printed circuits or like structures characterised by the terminals terminals for insertion into holes
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R12/00Structural associations of a plurality of mutually-insulated electrical connecting elements, specially adapted for printed circuits, e.g. printed circuit boards [PCB], flat or ribbon cables, or like generally planar structures, e.g. terminal strips, terminal blocks; Coupling devices specially adapted for printed circuits, flat or ribbon cables, or like generally planar structures; Terminals specially adapted for contact with, or insertion into, printed circuits, flat or ribbon cables, or like generally planar structures
    • H01R12/70Coupling devices
    • H01R12/71Coupling devices for rigid printing circuits or like structures
    • H01R12/72Coupling devices for rigid printing circuits or like structures coupling with the edge of the rigid printed circuits or like structures
    • H01R12/722Coupling devices for rigid printing circuits or like structures coupling with the edge of the rigid printed circuits or like structures coupling devices mounted on the edge of the printed circuits
    • H01R12/724Coupling devices for rigid printing circuits or like structures coupling with the edge of the rigid printed circuits or like structures coupling devices mounted on the edge of the printed circuits containing contact members forming a right angle
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R43/00Apparatus or processes specially adapted for manufacturing, assembling, maintaining, or repairing of line connectors or current collectors or for joining electric conductors
    • H01R43/20Apparatus or processes specially adapted for manufacturing, assembling, maintaining, or repairing of line connectors or current collectors or for joining electric conductors for assembling or disassembling contact members with insulating base, case or sleeve
    • H01R43/24Assembling by moulding on contact members
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R13/00Details of coupling devices of the kinds covered by groups H01R12/70 or H01R24/00 - H01R33/00
    • H01R13/40Securing contact members in or to a base or case; Insulating of contact members
    • H01R13/405Securing in non-demountable manner, e.g. moulding, riveting
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R13/00Details of coupling devices of the kinds covered by groups H01R12/70 or H01R24/00 - H01R33/00
    • H01R13/46Bases; Cases
    • H01R13/502Bases; Cases composed of different pieces
    • H01R13/506Bases; Cases composed of different pieces assembled by snap action of the parts
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R2103/00Two poles
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R2201/00Connectors or connections adapted for particular applications
    • H01R2201/26Connectors or connections adapted for particular applications for vehicles

Definitions

  • the invention relates to a connector, in particular a mini-coax automotive connector, for connection to a compatible connector device, and a method for manufacturing a connector.
  • Connectors in particular connectors for automotive applications, have to meet a large number of requirements.
  • connectors must enable safe and reliable transmission of electrical signals, such as high-frequency signals.
  • the plug connectors must be durable and, due to the usually limited space available at the intended installation site, have small dimensions and be designed as compactly as possible.
  • FAKRA plug
  • a plug connector can have a form coding according to which a corresponding plug device can be connected to the plug connector.
  • the shape coding ensures that the plug device can only be connected to the plug connector in accordance with one plug-in option.
  • the coding of the plug connector and the complementary plug device can be carried out in accordance with desired FAKRA standards.
  • connectors have a large number of parts or components, which are assembled to form the connector. It is important that the manufacture or production of connectors is possible in a consistent quality and that the production can be carried out quickly.
  • the first dielectric insulation element and the second dielectric insulation element prevent the inner contact or the first contact section and the second contact section of the inner contact from being angled beyond the predetermined angle during the manufacture of the connector.
  • the first dielectric insulation element serves as an insulator, which electrically insulates the inner contact of the coaxial connector from the sleeve, thereby reducing the number of components in the connector and thus the complexity of the connector.
  • the inner contact Since the inner contact is intended to connect the coax socket of the compatible plug device to the printed circuit board, the inner contact usually has to be angled. Particularly in the case of arrangements of the plug connector on the printed circuit board in which the connection direction and the printed circuit board are not aligned perpendicularly to one another, it is necessary to bend the inner contact in order to be able to connect the coaxial socket to the printed circuit board.
  • the connection direction is to be understood as the direction in which the connector must be guided in order to connect the connector to the compatible connector device.
  • the connection direction is essentially parallel to the longitudinal direction or cylinder axis of the sleeve of the coaxial connector.
  • the predetermined angle can preferably be essentially 90°.
  • the inner contact of the connector can be punched out of a flat starting workpiece during production.
  • a sheet metal made of an electrically conductive metal can be used as a flat starting workpiece, which has a predetermined material strength or thickness.
  • the inner contact punched out of the starting workpiece is elongate and flat and has no contact sections which are angled to one another. Further the material thickness or the thickness of the starting workpiece can be between 0.2 mm and 0.4 mm and preferably about 0.3 mm.
  • the first dielectric insulation element and the second dielectric insulation element can each have a stop surface, which are aligned essentially parallel to one another when the predetermined angle is present.
  • the first dielectric insulation element and the second dielectric insulation element are each designed as insulation bodies which (completely) surround the inner contact at least in sections along its longitudinal direction.
  • the first dielectric insulation element and the second dielectric insulation element completely surround the outer circumference of the inner contact at least in sections along the longitudinal direction of the inner contact.
  • the first dielectric insulation element and the second dielectric insulation element are preferably arranged at a distance from one another on the inner contact.
  • the inner contact has an exposed portion that is not surrounded by an isolation element.
  • the exposed section can have an angled course, corresponding to the angling of the first contact section relative to the second contact section.
  • the first dielectric insulation element and/or the second dielectric insulation element can preferably be formed on the inner contact or on the first contact section and/or on the second contact section by means of an injection molding process.
  • the insulation element can thus be formed on the inner contact in a simple manner.
  • the inner contact can be arranged on an injection mold which provides recesses for the first dielectric insulation element and/or the second dielectric insulation element.
  • the injection mold or the recesses can be filled with a liquefied dielectric insulating material, or a plastic, and the insulating material is then solidified, for example by cooling.
  • the inner contact with the arranged first dielectric insulation element and/or second dielectric insulation element can then be removed from the injection mold.
  • the first contact section can preferably have an end section on the coax socket side, which is designed to engage in a socket-shaped inner contact of a corresponding coax socket of the compatible plug device and/or the second contact section can have an end section on the printed circuit board side, which is designed to electrically connect to the circuit board to be connected.
  • the respective end sections correspond to the respective ends of the inner contact.
  • the circuit board-side end section is guided outwards from the housing body, so that the circuit board-side end section can be arranged in a passage opening of the circuit board in order to electrically connect the coaxial connector to the circuit board.
  • the end section on the coax socket side and the end section on the printed circuit board side preferably have a substantially round and/or oval cross section transversely to the longitudinal direction of the inner contact.
  • the cross section/diameter of the end section on the coax socket side can be 0.2 mm to 0.4 mm, for example.
  • the cross section of the end section on the coax socket side can have an essentially rectangular basic shape with dimensions of approximately 0.3 mm*0.37 mm, with a radius of approximately 0.1 mm being stamped on all edges. Due to the embossed radius, the cross section of the end section on the coax socket side has the previously mentioned essentially round or oval shape.
  • the diameter of the end section on the circuit board side can be 0.2 mm to 0.5 mm, for example.
  • the cross section of the end section on the circuit board side can have an essentially rectangular basic shape with dimensions of approximately 0.3 mm*0.37 mm, with a radius of approximately 0.1 mm being stamped on all edges.
  • the end section on the coax socket side and/or the end section on the printed circuit board side can be formed by embossing the inner contact will.
  • the inner contact punched from the starting workpiece can be subjected to a stamping process, in which the end section on the coax socket side and/or the end section on the printed circuit board side, which have a substantially rectangular cross section (transverse to the longitudinal direction) after stamping, are processed in such a way that the cross section in Substantially round and / or oval.
  • Embossing is particularly advantageous since burr formation on the end section on the coax socket side and/or the end section on the printed circuit board side can be prevented.
  • the end section on the coax socket side and/or the end section on the printed circuit board side are not surrounded by the first dielectric insulation element and/or the second dielectric insulation element.
  • the first dielectric insulation element can preferably have a sleeve section and a housing section, the sleeve section being surrounded by the sleeve and the housing section being arranged at least in sections in a form-fitting manner in a first insulation element receiving space of the housing body.
  • the sleeve section of the first dielectric insulation element is of essentially cylindrical design, with the end section on the coax socket side projecting out of the sleeve section pointing in the connection direction. Furthermore, the sleeve section is formed between the exposed end section on the coax socket side and the housing section of the first dielectric insulation element. The sleeve can preferably be slid onto the sleeve section from the direction of the end section on the coax socket side, counter to the connection direction.
  • the transition from the sleeve section to the housing section can function as a stop against which a base of the sleeve rests when the sleeve is arranged on the sleeve section.
  • the plug connector can thus be easily manufactured in that the sleeve can be slid onto a defined position of the first dielectric insulation element.
  • the form fit between the housing section and the prevents housing body prevents twisting of the inner contact in the housing body, which further facilitates the manufacture of the plug connector.
  • the housing body can have a passage opening, by means of which the first contact section of the coaxial plug connector is guided outwards at least in sections from the housing body in the connection direction.
  • the sleeve pushed onto the sleeve section can be arranged at least in sections in the through-opening and can be guided out of the housing body through the through-opening in the connection direction.
  • the passage opening can essentially be configured as a cylindrically shaped recess in the housing body, which is adjoined by the first insulating element receiving space counter to the connection direction.
  • the first insulation element receiving space can have a rectangular, in particular square, cross section transversely to the connection direction.
  • the housing section can have a shape corresponding to the first insulating element receiving space, so that the above-mentioned positive arrangement of the housing section on the first insulating element receiving space is possible.
  • the first insulating element receiving space can have a larger cross section than the passage opening, so that the transition from the first insulating element receiving space to the passage opening provides a stop.
  • the stop or shoulder formed by the sleeve section and the housing section can rest against the stop formed by the passage opening and the first insulating element receiving space when the coaxial connector or the first contact section of the coaxial connector in the connection direction into the first insulating element receiving space and then through the passage opening is passed through.
  • the base of the sleeve can be located between both stops, whereby the sleeve is secured in the housing body.
  • the housing section of the first dielectric insulation element can preferably have guide elements for guiding an insertion movement of the first dielectric insulation element into the housing body or into the first insulation element receiving space.
  • the housing body can preferably have a second insulating element receiving space in which the second dielectric insulating element is arranged in a form-fitting manner.
  • the longitudinal direction of the second insulation element receiving space corresponds to the longitudinal direction of the second contact section of the coaxial connector.
  • the longitudinal direction of the second insulating element receiving space can be essentially perpendicular to the longitudinal direction of the passage opening or the first insulating element receiving space.
  • the second insulating element receiving space can have a rectangular, in particular square, cross-section transversely to its longitudinal direction or transversely to the longitudinal direction of the second contact section.
  • the second dielectric insulation element can have a shape corresponding to the second insulation element receiving space, so that the positive arrangement mentioned above is possible.
  • the second contact section can preferably be guided outwards at least in sections through the second insulating element receiving space out of the housing body, so that the second contact section and in particular the circuit board-side end section of the inner contact can be connected to the circuit board.
  • the circuit board-side end section is not surrounded by the second dielectric insulation element, as a result of which the circuit board-side end section is exposed.
  • the second contact section and in particular the printed circuit board-side end section can be arranged at least in sections in a through-contact on the printed circuit board in order to electrically connect the inner contact to the printed circuit board.
  • the housing body can have a first housing body element and a second housing body element, wherein the first housing body element is designed to receive the first dielectric insulation element and the second housing body element is designed to receive the second dielectric insulation element, and the second housing body element is inserted into the first housing body element is.
  • the provision of the first housing body element and the second housing body element enables the connector to be easily assembled or manufactured.
  • the first housing body can have the passage opening and the first insulating element receiving space, into which the first contact section of the coaxial connector can be inserted.
  • the second case body member may have the second insulating member accommodating space.
  • the first contact section can be inserted into the first housing body element and in particular into the first insulating element receiving space and into the through-opening, so that the first contact section is at least partially routed through the through-opening to the outside.
  • the second contact portion can be angled to the predetermined angle relative to the first contact portion.
  • the second housing body element can then be inserted into the first housing body element, as a result of which the second dielectric insulation element is arranged in the second insulation element receiving space and the second contact section, at least in sections and in particular the end section on the circuit board side, is led out of the housing body or the second housing body element.
  • the order can also be reversed by first inserting the second contact portion of the coaxial connector into the second housing body member to insert the second dielectric insulating member into the second To arrange insulation element receiving space. Before or after that, the first contact portion can be angled to the predetermined angle relative to the second contact portion. Then, the second housing body member can be inserted into the first housing body member toward the connection direction, thereby arranging the first contact portion of the coaxial connector in the first housing body member. In particular, the first contact section of the coaxial plug connector is guided outwards from the housing body, at least in sections, through the first insulating element receiving space and the passage opening.
  • the first housing body element can preferably have deformable securing elements, with which the second housing body element is secured to the first housing body element.
  • the deformable fuse elements are deformed, for example by bending, after the second housing body element has been inserted into the first housing body element.
  • the deformable fuse elements can be formed on an underside of the housing body or the first housing body element, with the underside facing the printed circuit board when the plug connector is arranged on the printed circuit board.
  • the second housing body element can preferably be held in the first housing body element by the deformable securing elements.
  • the plug connector can preferably have four coax plug connectors, particularly preferably exactly four coax plug connectors, for connection to corresponding coax sockets of the compatible plug device, the four coax plug connectors being aligned parallel to one another and having a rectangular plug-in arrangement.
  • the four coaxial plug connectors can be guided to the outside through a side pointing in the connection direction, hereinafter referred to as the front side, of the housing body or the first housing body element.
  • the housing body or the first housing body element has four through-openings in accordance with the through-opening explained above, through which the coaxial plug connectors can be passed at least in sections in the connection direction be led outside.
  • the through openings also extend through the front side.
  • the front side can have an essentially rectangular, preferably square shape, with a coaxial connector being arranged in each quadrant of the front side.
  • the second housing body element can have two mutually stepped receiving areas for receiving the second dielectric insulation elements, each receiving area providing two second insulating element receiving spaces.
  • the second insulation element receiving spaces are of different lengths in the respective receiving areas, with second insulating element receiving spaces of the same receiving area being of the same length.
  • the connector can preferably have a connection housing that can be connected to the housing body for connecting the connector to the compatible plug device, the connection housing surrounding the coaxial connector at least in sections along the connection direction, and the connection housing being connectable to the housing body in at least two different orientations.
  • the connector can be preconfigured with a predetermined orientation of the connection housing on the housing body, so that based on the selected orientation, the compatible connector device can be plugged into the connector in a specific spatial arrangement direction with respect to the connector.
  • a plug device angled at right angles to point away from the plug connector in different directions, depending on the selected orientation.
  • the plug connector allows an orientation to be selected in which the plug device can be used under the given space conditions.
  • the plug connector can be arranged on a printed circuit board in order in particular to electrically connect the coaxial plug connector to the printed circuit board and electrical components arranged thereon.
  • connection housing By being able to choose the orientation of the connection housing in order to In order to use existing space optimally, a possibly necessary and usually complex revision of the circuit board layout, in particular the provision of a different fastening position or arrangement position of the connector on the circuit board, can be dispensed with. If necessary, only the electrical connection between the connector and the printed circuit board has to be adjusted, for example by changing the wiring on the printed circuit board side to connect the individual coaxial connectors to the printed circuit board. However, in comparison to a revision of the circuit board layout, in which the connector has to be arranged in a different position on the circuit board, this is much less complex.
  • the connector allows the connector device to be connected to the connector in a predetermined spatial orientation in relation to the connector, in order to be able to react flexibly to given space conditions.
  • the plug connector can preferably be designed as a standard-compliant plug connector, which in particular conforms to a standard of the automotive sector, for example FAKRA HF and USCAR and in particular conforms to the standards DIN 72594-1 and USCAR-18.
  • connection housing can preferably be slipped onto a receiving base provided on the housing body and the connection housing and the receiving base can each have cooperating securing features with which the connection housing can be secured on the receiving base or the housing body.
  • the receiving socket can be formed on the first housing body element, with the coaxial plug connectors being guided outwards via the receiving socket in the connection direction.
  • the housing body can be designed as a zinc die-cast component and/or the connecting housing can be designed as a plastic component.
  • the housing body and the connection housing can thus be manufactured at low cost.
  • a zinc die-cast component executed housing body particularly stable.
  • the housing body can preferably have a positioning projection and the connecting housing can have at least two positioning openings, the positioning projection and the at least two positioning openings being arranged in such a way that in each orientation in which the connecting housing can be connected to the housing body, the positioning projection can be inserted into a different positioning opening of the at least two Positioning holes engages.
  • the plug connector can have features of the plug connector explained above.
  • the method can have further features corresponding to the above statements.
  • FIG 1 shows a connector 10 consisting of a housing body 12 and a connection housing 14, which can be plugged onto the housing body 12.
  • the connector 10 is designed in particular as a mini-coax automotive connector and can be connected to a compatible connector device.
  • the housing body 12 further consists of a main housing body section 16 and a receiving socket 18 which is arranged on the main housing body section 16 and points in the direction of a connection direction V.
  • the connection direction V is to be understood as the direction in which the connector 10 must be moved in order to plug the housing body 12 into the connection housing 14 or in order to connect the connector 10 to a compatible connector device (not shown).
  • the housing body 12 has four coaxial plug connectors 20 which are arranged in the housing body 12 at least in sections.
  • the four coaxial plug connectors 20 are aligned essentially parallel to one another and are guided outwards from the housing body 12 via the receiving base 18 .
  • the four coax connectors 20 extend from the receiving base 18 in the connection direction V.
  • connection housing 14 has a section 22 on the receiving base, which can be plugged onto the receiving base 18 .
  • the section 22 on the receiving base is plugged onto the receiving base 18 and the receiving base 18 is preferably completely inserted into the section 22 on the receiving base.
  • the connection housing 14 has a connector device-side section 24 into which the compatible connector device can be plugged in order to connect corresponding coaxial sockets of the connector device to the coaxial connectors 20 .
  • the connector 10 can in particular be a standard-compliant connector that conforms to a FAKRA standard or a USCAR standard, for example. Furthermore, the connector 10 has a form coding 26 formed on the connection housing 14, which ensures that the Connection housing 14 has exactly one insertion option for inserting the compatible connector device. As in figure 1 shown, the form coding 26 can consist of one or more grooves 26 which extend along the connection direction V on the inside of the connector device-side section 24 of the connection housing 14 .
  • connection housing 14 is designed to be fastened in at least two different orientations to the housing body 12 or to the receiving base 18 .
  • the connection housing 14 can be attached to the housing body 12 in different orientations by rotating the connection housing 14 by 90° about a central axis Z, which extends from the center of the receiving base 18 in the direction of the connection direction V. in the in figure 1
  • the connection housing 14 can be arranged in (precisely) four different orientations on the housing body 12 or on the receiving base 18 .
  • the coax connectors 20 are assigned to different coax jacks of the compatible connector device.
  • figure 2 by way of example, how the connection housing 14 is arranged in a first orientation on the housing body 12 or on the receiving base 18 .
  • the receiving base 18 has a front side 28 pointing in the connection direction V, which is essentially perpendicular to the connection direction V. That is, the normal vector of the front side 28 is essentially parallel to the connection direction V.
  • the front side 28 has an essentially square shape (also compare FIG Figures 3 and 4 ), wherein one narrow side 30 each extends from the four sides of the front side 28 in the direction of the main housing body section 16 counter to the connection direction V in order to connect the front side 28 to the main housing body section 16 .
  • the narrow sides 30 each have a security feature 32, which can be combined with corresponding security features 34 (see figure 4 ) of the connector housing 14 cooperate to secure the connector housing 14 to the housing body 12 and the receptacle socket 18, respectively.
  • FIG. 12 shows an exploded perspective view of the housing body 12.
  • the housing body 12 consists of a first housing body element 36 and a second housing body element 38, the second housing body element 38 being insertable into the first housing body element 36.
  • the first housing body element 36 has the receiving base 18 in which four passage openings 40 are formed, which extend in the connection direction V.
  • the passage openings 40 are such that the coaxial plug connectors 20 are led out of the housing body 12 by means of the passage openings 40 pointing outwards in the connection direction V.
  • a coaxial connector 20 has an electrically conductive inner contact 42 (see Figures 6 and 7 ) which is essentially flat and elongate. Furthermore, the inner contact 42 is designed to connect a coaxial socket of the compatible plug device to a printed circuit board.
  • the inner contact 42 can in particular be stamped from a flat starting workpiece.
  • a sheet metal made of an electrically conductive metal can be used as a flat starting workpiece, which has a predetermined material strength or thickness.
  • the material thickness or thickness of the electrically conductive starting workpiece can be between 0.2 mm and 0.4 mm, for example, and preferably about 0.3 mm or exactly 0.3 mm.
  • the inner contact 42 can be divided into a first contact section 44 and a second contact section 46, the second contact section 46 being angled at a predetermined angle relative to the first contact section 44 (cf figure 3 to figure 6 ).
  • the first contact section 44 is angled by approximately 90° relative to the second contact section 46 .
  • the inner contact 42 in the area of the first contact section 44 has a coaxial socket-side end section 110 which is formed at one end of the inner contact 42 . Furthermore, the end section 110 on the coax socket side is designed to engage in a socket-shaped inner contact of a corresponding coax socket of the compatible plug device.
  • the inner contact 42 can have an end section 112 on the circuit board side, which is formed at the other end of the inner contact 42 .
  • the circuit board side end portion 112 is designed to be electrically connected to the circuit board.
  • the circuit board-side end section 112 is led out of the housing body 12 so that the circuit board-side end section 112 can be arranged in a passage opening of the circuit board in order to electrically connect the coaxial connector 20 to the circuit board.
  • the end section 110 on the coax socket side and/or the end section 112 on the printed circuit board side can be formed by embossing the inner contact 42 .
  • the inner contact 42 stamped from the starting workpiece can be subjected to a stamping process, in which the end section 110 on the coax socket side and/or the end section 112 on the printed circuit board side, which after stamping has a substantially rectangular cross section (transverse to the longitudinal direction of the inner contact 42), are shaped in this way be that the cross-section is essentially round and/or oval. Embossing is particularly advantageous since burr formation on the end section 110 on the coax socket side and/or the end section 112 on the printed circuit board side can be prevented.
  • the end section 110 on the coax socket side and the end section 112 on the printed circuit board side preferably have a substantially round or oval cross section transversely to the longitudinal direction of the inner contact.
  • the cross section/diameter of the end section 110 on the coax socket side can be 0.2 mm to 0.4 mm, for example.
  • the cross section of the end section 110 on the coax socket side can particularly preferably have a substantially have a rectangular basic shape with the dimensions of approx. 0.3mm*0.37mm, with a radius of approx. 0.1mm being stamped on all edges. Due to the stamped radius, the cross section of the end section 110 on the coax socket side has the above-mentioned essentially round or oval shape.
  • the diameter of the circuit board-side end section 112 can be 0.2 mm to 0.5 mm, for example.
  • the cross section of the printed circuit board-side end section 112 can have an essentially rectangular basic shape with dimensions of approximately 0.3 mm*0.37 mm, with a radius of approximately 0.1 mm being stamped on all edges.
  • the inner contact 42 in the region of the first contact section 44 is surrounded at least in sections along the longitudinal direction of the inner contact 42 by a first dielectric insulation element 48, with the end section 110 on the coax socket being exposed, i.e. not being surrounded by the first dielectric insulation element 48.
  • the inner contact 42 is surrounded at least in sections by a second dielectric insulation element 50 in the region of the second contact section 46, with the first dielectric insulation element 48 and the second dielectric insulation element 50 being arranged at a distance from one another on the inner contact 42 if the inner contact 42 is not angled.
  • the circuit board-side end section 112 is exposed and not surrounded by the second dielectric insulation element 50 .
  • the first dielectric insulation element 48 and the second dielectric insulation element 50 can be connected to the inner contact 42 or arranged on it, in particular using an injection molding process.
  • the inner contact 42 can be arranged on an injection mold which provides recesses for the first dielectric isolation element 48 and/or the second dielectric isolation element 50 .
  • the injection mold or the recesses can be filled with a liquefied dielectric insulating material or a plastic, and the insulating material is then solidified, for example by cooling.
  • the inner contact 42 with the arranged first dielectric insulation element 48 and/or second dielectric insulation element 50 can be removed from the injection mold.
  • the insulation elements created in this way can also be referred to as insulation bodies be in which the inner contact 42 is arranged at least in sections.
  • first dielectric insulation element 48 and the second dielectric insulation element 50 each have a stop surface 52 (see FIG figure 7 ), which limit the angling of the first contact section 44 relative to the second contact section 46 to the predetermined angle, for example approximately 90°.
  • the stop surface 52 of the first dielectric isolation element 48 and of the second dielectric isolation element 50 are aligned essentially parallel to one another.
  • the first dielectric insulation element 48 has a sleeve section 56 which at least partially surrounds the inner contact 42 along the connection direction V.
  • the sleeve section 56 adjoins the end section 110 on the coaxial socket side counter to the connection direction V (directly).
  • a housing section 58 of the first dielectric insulation element 48 adjoins (directly) the sleeve section 56 .
  • the sleeve section 56 has an essentially cylindrical shape, the cylinder axis of the sleeve section 56 lying essentially parallel to the longitudinal direction of the first contact section 44 and essentially coinciding with the end section 110 on the coaxial socket side.
  • the housing section 58 has a rectangular, preferably square, cross-section transversely to the longitudinal direction. Furthermore, the cross-sectional area of the housing section 58 is selected to be larger than the cross-sectional area of the sleeve section 56, so that a stop or step is formed at the transition from the sleeve section 56 to the housing section 58, which is referred to below as the sleeve stop 114.
  • the coaxial plug connector 20 has an essentially hollow-cylindrical sleeve 54 which can be pushed onto the sleeve section 56 counter to the connection direction V.
  • the sleeve 54 has a sleeve base 55 which is formed radially outwards and rests against the sleeve stop 114 .
  • the first dielectric isolation member 48 electrically insulates the sleeve 54 from the inner contact 42.
  • the sleeve 54 completely surrounds the end section 110 on the coax socket side along the connection direction V.
  • the sleeve 54 and the end section 110 on the coax socket side are thus designed to be connected to a coax socket of the compatible plug device.
  • the sleeve section 56 is arranged between the sleeve 54 and the inner contact 42 .
  • the second dielectric insulation element 50 has a rectangular, preferably square, cross-section transversely to the longitudinal direction of the inner contact 42 .
  • the first housing body has a first insulating element receiving space 60 which adjoins the passage opening 40 of the receiving base 18 counter to the connection direction V.
  • the first contact section 44 is arranged at least in sections in the first insulating element receiving space 60 and the passage opening 40 .
  • the first contact section 44 is inserted with the end section 110 on the coax socket first, in the connection direction V, into the first insulating element receiving space 60 and into the passage opening 40 in order to guide the sleeve 54 out of the housing body 12 to the outside.
  • the passage opening 40 rests flat against the sleeve 54 .
  • the first insulating element receiving space 60 has a rectangular, preferably square, cross-section transversely to the connection direction V, so that the first dielectric insulating element 48 is arranged in a form-fitting manner in the first insulating element receiving space 60 .
  • the first insulating element receiving space 60 can have a larger cross section than the passage opening 40, so that the transition from the first insulating element receiving space 60 to the passage opening 40 provides a stop 115 or shoulder.
  • the sleeve base 55 can be arranged between both stops 114/115, as a result of which the sleeve 54 is secured in the housing body 12.
  • the second contact portion 46 may be angled with respect to the first contact portion 48 to the predetermined angle.
  • the second housing body element 38 is then inserted into the first housing body element 36 in such a way that the second contact section 46 and in particular the circuit board-side end section 112 is guided out of the second housing body element 38 and thus out of the housing body 12 or to the outside.
  • the second housing body element 38 has in particular a second insulating element receiving space 62 which is designed to receive the second dielectric insulating element 48 preferably in a form-fitting manner.
  • the longitudinal direction of the second insulating element receiving space 62 is essentially perpendicular to the connection direction V or corresponds to the longitudinal direction of the second contact section 46.
  • the second insulating element receiving space 62 has a substantially rectangular, preferably square, cross section transverse to the longitudinal direction, so that the second dielectric insulating element 50 can be arranged in a form-fitting manner in the second insulating element receiving space 62 .
  • the second insulating element receiving space 62 provides an opening on the underside 64 of the second housing body element 38 or the housing body 12, through which the second contact section 46 or the circuit board-side end section 112 can be led to the outside.
  • the underside 64 of the second housing body member 38 or housing body 12 is in one arrangement of the case body 12 on the circuit board facing the circuit board.
  • the housing section 58 of the first dielectric insulation element 48 has guide elements 59 (see FIG figure 3 ), which support insertion of the first dielectric insulation element 48 into the first housing body element 36 or into the first insulation element receiving space 62 .
  • the guide elements 59 can in particular be designed as projections on the housing section 58 .
  • the second housing body element 38 has a total of four second insulating element receiving spaces 66, in each of which a second dielectric insulating element 50 can be arranged in a form-fitting manner. Furthermore, the second housing body element 38 has two mutually stepped receiving areas 66/68, each receiving area 66/68 providing two second insulating element receiving spaces 63. Furthermore, the four second insulating member accommodating spaces 63 are separated from each other by walls 70 of the second housing body member 38, respectively. Furthermore, the second insulating element receiving spaces 62 are open towards the underside 64 . Furthermore, the second insulation element receiving spaces 62 are of different lengths in the respective receiving areas 66/68, with second insulating element receiving spaces 62 of the same receiving area 66/68 being of the same length. The length of the second dielectric insulation elements 50 assigned to the respective second insulation element receiving spaces 62 is correspondingly formed.
  • the first housing body 12 or the main housing body section 16 has two opposite side walls 72 which extend from the underside 64 of the housing body 12 to an upper side 74 of the housing body 12 . Furthermore, the side walls 72 of the first housing body element 12 are aligned essentially parallel to the connection direction V. FIG. Furthermore, the two sidewalls 72 are spaced apart such that the second housing body member 38 is sandwiched between the two sidewalls 72 of the first housing body member 36 .
  • At the bottom of the two Side walls 72 are each formed with two plug contacts 74, by means of which the housing body 12 can be connected to a printed circuit board. In particular, the plug contacts 74 can be inserted into plug-in holes formed on the landing circuit board and then connected to the circuit board, for example by soldering.
  • each side wall 72 has a support element 76 with a support surface 78 on the underside 64 .
  • the support element 76 and the support surface 78 serve to support the housing body 12 or the connector 10 on the printed circuit board, so that the coaxial connectors 20, which are preferably used for electrical contact, and the plug contacts 74 do not additionally weigh the connector 10 or the Housing body 12 "wear" must.
  • the connector 10 thereby has advantages in terms of vibration resistance.
  • the support elements 76 and/or the plug contacts 74 can be used to dissipate heat from the printed circuit board.
  • the second housing body element 38 has one or more support elements 76 with corresponding support surfaces 78 on the underside 64 .
  • deformable securing elements 80 are formed on the underside 64 of the side walls 72 with which the second housing body element 38 can be secured on the first housing body element 36 .
  • securing it is meant that the second housing body member 38 cannot be separated from the first housing body member 36 .
  • each side wall 72 has one, preferably precisely one, deformable securing element 80 at an end of the underside 64 lying in the connection direction V and at an end of the underside 64 lying opposite to the connection direction V.
  • the securing element 80 is in each case designed as a projection which extends away from the housing body 12 starting from the underside 64 .
  • the second housing body element 38 has recesses 82 on the underside, into which the securing elements 80 engage when the securing elements 80 are deformed or bent in the direction of the opposite side wall 72 .
  • the recesses 82 are provided in the corners of the underside 64 of the second housing body element 38, respectively.
  • a partition wall 84 is arranged between the section 22 on the receiving base and the section 24 on the connector device side, which is arranged essentially perpendicularly to the connection direction V.
  • the partition 84 also has four passage openings 86 through which the four coaxial connectors 20 are passed.
  • the connector device-side section 24 surrounds the four coaxial connectors 20 at least in sections in the connection direction.
  • the partition wall 84 and the wall 88 of the connector-device-side section delimit a receiving space into which the compatible connector device is inserted in the direction of the insertion direction E.
  • a wall 90 of the section 22 of the connection housing 14 on the receiving base extends counter to the connection direction V.
  • the partition 84 and the wall 90 delimit the section 22 on the receiving base, into which the receiving base 18 is inserted or plugged.
  • the partition wall 84 rests against the front side 28 of the receiving base 18 .
  • the inside of the wall 90 of the section 22 on the receiving base also rests against the narrow sides 30 of the receiving base 18 .
  • the securing features 34 of the connection housing 14 are formed on the inside of the wall 90 of the socket-side section 22 , which cooperate with the securing features 32 of the receiving socket 18 in order to secure the connection housing 14 to the housing body 12 .
  • the securing features 34 of the connection housing 14 can be formed as recesses.
  • the securing features 32 of the receiving base can be designed as projections which are arranged on the outside on the narrow sides 30 .
  • each of the four narrow sides 30 can have a security feature 32 and the inside of the wall 90 can have corresponding security features 34.
  • the securing feature 32, designed as a projection, of the receiving base 18 has a direction in the connection direction V descending ramp 92 up. Contrary to the connection direction V, the securing feature 32 designed as a projection drops in steps or perpendicularly onto the narrow side 30 . In particular, it can thus be achieved that the connection housing 14 cannot be separated from the housing body 12 without destroying it, since the shape of the securing feature 32 embodied as a projection results in at least damage to the connection housing 14 .
  • the front side 28 of the receiving base 18 has two spaced-apart positioning projections 94 which extend from the front side 28 in the connection direction V. Furthermore, the partition wall 84 of the connection housing 14 has four positioning holes 96 (cf. figure 8 ), About what figure 3 only partially shows three positioning openings 96 due to the sectional drawing. The positioning projections 94 and the positioning openings 96 are arranged such that in each orientation of the connection housing 14 on the housing body 12, one positioning projection 94 engages another positioning opening 96 .
  • the positioning openings 96 and positioning projections 94 have a substantially triangular shape, preferably an isosceles triangular shape, and more preferably a simultaneous triangular shape. Furthermore, the two positioning projections 94 are arranged opposite one another on the front side 28 of the receiving base 18 . Each positioning projection 94 is centered on an edge 31 which is formed by the front side 28 and a narrow side 30 aligned. In particular, one side of the triangle can be aligned with edge 31 . Also, an isosceles triangle has its base aligned with edge 31 . Further, the four positioning holes 96 are arranged on the partition wall 84 corresponding to the positioning projections 94 .
  • the four positioning holes 96 are formed in the partition wall 84 at intervals of 90 degrees.
  • the four positioning openings 96 can be arranged on the partition wall 84 in such a way that two imaginary connecting lines, which in each case connect two opposite positioning openings 96, have a common point of intersection.
  • the four positioning holes 96 are formed in the partition wall 84 at 90° intervals (the intersection point being the center of an imaginary circle on which the four positioning holes 96 lie).
  • an imaginary straight line substantially perpendicular to the partition wall 84 and passing through the common intersection intersects an imaginary connecting line connecting the two positioning projections 94 such that the two positioning projections 94 are equidistant from the imaginary straight line.
  • the imaginary straight line runs through the center point of the front side 28 of the receiving base 18.
  • the housing body 12 has recesses 98 on its outer wall, which on the basis of the Figures 9-11 be explained in more detail.
  • the recesses 98 can in particular be in the form of indentations which are formed on the outer wall of the housing body 12 .
  • the housing body 12 or the main housing body section 16 has two opposite main sides 100 on the outside, which are formed by the side walls 72 of the first housing body element 36 and which connect the underside 64 of the housing body 12 to a top side 102 of the housing body 102 opposite the underside.
  • the main sides 100, the top 102 and the bottom 64 extend essentially parallel to the connection direction V.
  • the main sides 100 correspond to the outer sides of the side walls 72 of the first housing body element 36.
  • a first pair of recesses 104 and a second pair of recesses 106 are formed on both main sides 100 and in both side walls 72, with the first pair of recesses 104 extending from the top 102 in the direction of the underside 64 and the second pair of recesses 106 extending extends from bottom 64 toward top 102 .
  • the longitudinal direction of the recesses 98 is essentially perpendicular to the connection direction V.
  • the recesses 98 are formed in such a way that the depth a of the first pair of recesses 104 is greater than the width b of the first pair of recesses 106 (cf. figure 10 ), and the depth d of the second pair of recesses 106 is smaller than the width e of the second pair of recesses 106 (cf. figure 11 ). Furthermore, these are the first pair of recesses 104 and the second pair of recesses 106 on the two main sides 100 are not continuous and are located opposite one another (cf. figure 9 ).
  • the width b of a recess 98 in the first pair of recesses 104 and the width e of a recess 98 in the second pair of recesses 106 can be 0.04 to 0.08 times, particularly preferably approximately 0.057 times, the total width B of the case body 12 along the connection direction V.
  • the overall width B of the housing body can also be viewed as the distance between two notional planes, each of which is perpendicular to the connection direction V, and a first notional plane of the two notional planes at an end of the housing body 12 lying in the connection direction V (without a coaxial connector ) and a second imaginary plane of the two imaginary planes is located at an end of the housing body 12 opposite to the connection direction V.
  • the overall width B of the housing body 12 can be, for example, in the range between 11 mm and 18 mm and preferably in the range between 13 mm and 16 mm.
  • the overall width B of the housing body 12 is essentially 15.8 mm and the width b of a recess 98 of the first pair of recesses 104 and the width e of a recess 98 of the second pair of recesses 106 is essentially 0.9 mm.
  • the depth a of a recess 98 of the first pair of recesses 104 can be 0.10 times to 0.14 times the distance T between the two opposite main sides 100 .
  • the depth a of a recess 98 of the first pair of recesses can be approximately 0.117 times the distance T of the two opposite main sides 100 .
  • the depth d of a recess 98 of the second pair of recesses 106 can be 0.045 times to 0.07 times the distance T of the two opposite main sides 100 . In the most preferred embodiment, the depth d of a recess 98 of the second pair of recesses 106 may be approximately 0.055 times the distance T of the two opposing major sides 100 .
  • the distance T between the two main sides 100 of the housing body 12 can be 10 mm to 13 mm.
  • the distance T between the two main sides 100 of the housing body 12 is approximately 12 mm
  • the depth a of a recess 98 of the first pair of recesses 104 is approximately 1.41 mm
  • the depth d of a recess 98 of the second pair Recesses 106 about 0.66 mm.
  • first pair of cutouts 104 and the second pair of cutouts 106 are spaced at least 0.15 times and at most 0.25 times the total width B of the housing body along the connection direction V from a rear side 108 of the housing body.
  • first pair of recesses 104 and the second pair of recesses 106 may be spaced approximately 3.1 mm from the back 108 of the housing body.
  • the rear 108 is arranged opposite the front 28 and delimits the housing body 12 counter to the connection direction V.
  • the rear side 108 of the housing body 12 can be viewed as the side of the housing body 12 which is essentially perpendicular to the connection direction V and points counter to the connection direction.
  • the length c of the first pair of recesses 104 can be 0.2 to 0.4 times, preferably 0.3 to 0.38 times, the distance H between the bottom 64 and the top 102 of the housing body 12 correspond. In the most preferred embodiment, the length c of the first pair of recesses 104 may be approximately 0.37 times the distance H between the bottom 64 and top 102 of the housing body 12 .
  • the length f of the second pair of recesses 106 can correspond to 0.3 to 0.5 times, preferably 0.3 to 0.44 times, the distance H between the bottom 64 and the top 102 of the housing body . In the most preferred embodiment, the length f of the second pair of recesses 106 may be about 0.36 times the distance H between the bottom 64 and the top 102 of the housing body.
  • the distance H between the bottom 64 of the housing body 12 and the Top 102 of the housing body 12 is 10 mm to 14 mm, preferably 11 mm to 13 mm.
  • the distance H between the bottom 64 of the housing body 12 and the top 102 of the housing body 12 can be approximately 12.05 mm, the length f of the second pair of recesses 106 being approximately 5.7 mm and the length c of the first pair of recesses 104 can be about 4.45 mm.
  • the distance between the cutouts 98 of the first pair of cutouts 102 can be 1.3 to 2.0 times the width b of a cutout 98 of the first pair of cutouts 102 and the distance between the cutouts 98 of the second pair of cutouts 106 can be 1.3 to 2.0 times the width e of a recess 98 of the second pair of recesses 106 .
  • FIG 11 shows figure 11 how the support elements 76 are formed with their support surfaces 78 on the underside 64 of the first housing body element 36 .
  • the support surfaces 78 run essentially parallel to the underside 64 of the housing body 12 or the housing body element 36.
  • the support elements 76 are arranged in the connection direction V between two plug contacts 74.
  • first pair of plug contacts 74 which is arranged in the connection direction V in front of the second pair of plug contacts 74, forms a printed circuit board setting edge.
  • the printed circuit board setting edge corresponds in particular to an imaginary connecting line that connects the first pair of plug contacts 74 to one another.
  • the focus of the connector 10 is chosen so that the focus is opposite to the connection direction V behind the printed circuit board setting edge.
  • the connector 10 can be placed on the printed circuit board without the connector 10 tilting in relation to the printed circuit board.
  • the centroid is chosen to lie between two imaginary planes, the first imaginary plane passing through the first pair of pins 74, the second imaginary plane passing through the second pair of pins 74, and the first and second imaginary planes being substantially perpendicular to the Connection direction V stand.
  • FIG. 12 to 14 is a second embodiment of the housing body 12 and the first housing body element 36 shown.
  • the second embodiment differs from the embodiment described above in that it only has the first pair of recesses 104 on the respective main sides 100 of the first housing body element 36 .
  • the first pair of recesses 104 each extend from the top 102 of the housing body 36 in the direction of the bottom 64 of the housing body 36.
  • first pair of recesses 104 or a first recess 98 thereof, directly adjoins the rear side 108 of the housing body 36.
  • the other recess 98 ends in the connection direction V approximately at the level of the transition from the receiving base 18 to the main housing body section 16.
  • the width b of a cutout 98 of the first pair of cutouts 104 may be 0.3 to 0.4 times the total width B of the case body 12 along the connecting direction V (see FIG 14 ).
  • the overall width B of the housing body 12 can be between 11 mm and 14 mm, for example.
  • the overall width B of the housing body 12 is essentially 12.72 mm and the width b of a recess 98 of the first pair of recesses 104 is essentially 4.1 mm.
  • the depth a of a recess 98 of the first pair of recesses 104 can be 0.07 times to 0.1 times the distance T between the two opposite main sides 100 .
  • the distance T between the two main sides 100 of the housing body 12 can be 10 mm to 13 mm.
  • the depth a of a recess 98 of the first pair of recesses can be approximately 0.088 times the distance T of the two opposite main sides 100 .
  • the distance T between the two main sides 100 of the housing body 12 is approximately 11.35 mm and the depth a of a recess 98 of the first pair of recesses 104 is approximately 1 mm.
  • the length c of the first pair of recesses 104 can correspond to 0.7 to 0.9 times the distance H between the underside 64 and the upper side 102 of the housing body 12 . In the most preferred embodiment the length c of the first pair of recesses 104 can correspond to approximately 0.82 times the distance H between the bottom 64 and the top 102 of the housing body 12 .
  • the distance H between the bottom 64 of the housing body 12 and the top 102 of the housing body 12 can be 10 mm to 14 mm, in the particularly preferred embodiment approximately 11.1 mm.
  • the length c of the first pair of recesses 104 can be substantially 9.1 mm.
  • the distance between the cutouts 98 of the first pair of cutouts 102 can be 0.6 to 0.8 times the width b of a cutout 98 of the first pair of cutouts 102 .
  • a third embodiment of the housing body 12 or the first housing body element 36 is shown.
  • the third embodiment differs from the previously described embodiments in that the first housing body element 36 only has recesses 116 on the main sides 100 which are open towards the underside 64 and into which the second housing body element can engage with corresponding projections.
  • the housing body 12 of the third embodiment preferably has a distance H between the bottom 64 and the top 102 of approximately 9.5 mm, a distance T between the two opposite main sides 100 of approximately 10.3 mm, and an overall width B of the housing body 12 along the connection direction V by about 13 mm.
  • the sleeve 54 can preferably be produced in a few steps using the proposed method. Furthermore, with the proposed method, a sleeve 54 can be produced in a simple manner, which has the outside diameter and the wall thickness of a target sleeve.
  • a target sleeve is to be understood as a sleeve which is considered a sample or ideal sleeve and which specifies the shape properties to be achieved for a sleeve 54 to be produced.
  • the second predetermined wall thickness is smaller than the first predetermined wall thickness and the second predetermined outer diameter is smaller than the first predetermined outer diameter.
  • the initial workpiece provided can have a substantially flat and rectangular shape.
  • the starting workpiece has a starting area or size and a starting material thickness.
  • the surface of the starting workpiece can be enlarged and the material thickness of the starting material can be reduced.
  • the rolling or rolling of the starting workpiece can be terminated.
  • the rolling can be stopped when the predetermined material thickness is reached and the rolled starting workpiece can be cut into workpieces corresponding to the predetermined size, for example with a laser.
  • a large number of intermediate workpieces can be obtained from the starting workpiece, which can be further processed to form a sleeve 54 or sleeves.
  • the flat and substantially rectangular starting work piece is first formed into a sleeve shape in which two edges of the starting work piece face each other in an unconnected manner.
  • the sleeve shape that is still open in the longitudinal direction can be closed.
  • the two opposite edges can be connected by cohesive connection, in particular welding, of the two opposite edges.
  • the starting material can preferably have a length which makes it possible to cut a large number of sleeves, which have the length of the desired sleeve, from the starting workpiece having the third shape.
  • the manufacturing process for sleeves 54 can thus be made efficient.
  • the second predetermined wall thickness can be in the range from 0.1 mm to 0.5 mm, preferably in the range from 0.2 mm to 0.4 mm, and particularly preferably approximately 0.3 mm.
  • the second predetermined outer diameter can be between 2.0 mm and 4.0 mm, preferably between 2.2 mm and 3.0 mm, and particularly preferably approximately 2.8 mm.
  • the length of a sleeve 54 obtained, including the base can be between 9 mm and 12 mm, preferably between 9.5 mm and 11.5 mm, and particularly preferably around 9.75 mm.
  • the starting workpiece can preferably consist of an austenitic metal alloy which is preferably non-magnetic.
  • the metal alloy can have a chromium content of at least 8%, in particular at least 18%.
  • the chromium content is preferably about 18.27%.
  • the metal alloy has little or no magnetic conductivity.
  • the method can preferably have: Heat treatment of the starting workpiece.
  • the heat treatment can be performed before the starting workpiece is machined, or the finished sleeves 54 can be subjected to the heat treatment.

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  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Coupling Device And Connection With Printed Circuit (AREA)
EP21186911.0A 2020-07-22 2021-07-21 Connecteur enfichable, en particulier un connecteur enfichable automobile mini-coaxial, destiné à la connexion à un dispositif fiche compatible, ainsi que procédé de production d'un connecteur enfichable Pending EP3944422A1 (fr)

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DE102020209260.5A DE102020209260A1 (de) 2020-07-22 2020-07-22 Steckverbinder, insbesondere einen Mini-Koax-Automotive-Steckverbinder, zum Verbinden mit einer kompatiblen Steckervorrichtung sowie Verfahren zur Fertigung eines Steckverbinders

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