DE3784943T2 - ELECTRICAL TAP CONNECTOR ASSEMBLY. - Google Patents

Description

The present invention relates to the field of electrical branch connectors and more particularly to a branch connector assembly for coaxial cable networks.

An increasingly common use for electrical branch connectors is in the field of wiring within buildings. Wiring within buildings typically involves transmitting audio signals, electronic data and/or electrical power over one or more electrical conductors in a communications cable network. Workstations located at different locations are linked to the cable network by branch connectors.

The communication cable can be in different forms. For example, the cable can be a twisted pair cable containing insulated wires twisted together in spiral pairs. Alternatively, the cable can be a coaxial cable containing one or more insulated conductors surrounded by a cylindrical conductive sheath.

Branch connectors for coaxial cable networks were often relatively difficult to install and required special tools and skill to install them correctly. In addition, many coaxial branch connectors were not effective in maintaining the integrity of the overall network when the connectors were not in use. or when an external device was connected or disconnected from the network.

The present invention relates to a branch connector assembly comprising a connector housing, first and second signal transmission contacts carried by the housing and adapted to be electrically connected to signal transmission conductors of the first and second cables, respectively, and a third ground contact carried by the housing and adapted to be connected to conductive sheaths of the first and second cables, the housing being constructed to receive a complementary connector such that when the complementary connector is received, it engages the first, second and third contacts to electrically connect the first and second signal transmission contacts and the third ground contact to the complementary connector. The present invention consists in a branch connector assembly as defined in claim 1.

An embodiment of the present invention will now be described by way of example with reference to the accompanying drawings, in which:

Fig. 1 is an enlarged perspective view of a branch connector assembly;

Fig. 2 is a partially exploded perspective view of the branch connector assembly of Fig. 1;

Fig. 3 is a partially exploded sectional view of the female branch connector of Figs. 1 and 2;

Fig. 4 and 5 are sectional views of the branch connector arrangement of Fig. 1 to 3 in the unconnected state and in the connected state, respectively;

Figs. 6 and 7 are sectional views of the connector assemblies of Figs. 4 and 5 in the unconnected state and in the connected state, respectively, viewed in the direction of arrows 6-6 and 7-7 in Figs. 4 and 5, respectively;

Fig. 8 and 9 are sectional views of the connector assemblies of Fig. 4 and 5 in the unconnected state and in the connected state, respectively, viewed in the direction of arrows 8-8 and 9-9 in Fig. 4 and Fig. 5, respectively; and

Fig. 10 is a perspective view of the plug-type connector of Figs. 1 and 2, viewed from the rear.

Figures 1, 2, 4 and 5 show an electrical branch connector assembly. The connector assembly is generally designated by the reference numeral 10 and includes a female branch connector 6 which is integrable into an electrical cable network and a male connector 8 which is connectable to the female connector to connect external devices to the cable network. The connector assembly is specifically designed to provide access to a wiring system within buildings, although it should be understood that the invention is not intended to be limited to any particular application.

The socket-type branch connector 6 is designed to connect two cables 12a and 12b in the cable network. As can be seen in Figs. 2 and 3, the cables 12a and 12b include an outer jacket 21 made of polymeric insulating material, which coaxially and concentrically surrounds an electrically conductive grounding sheath 22. The electrically conductive sheath 22 in turn encloses an insulating sheath 23 which contains the one or more transmission lines of the cable. The transmission lines may include one or more electrical conductors and/or one or more optical fibers. In the embodiment described above, the cables are coaxial cables which include a single, signal-carrying, electrical center conductor 24 axially within the conductive outer sheath 22.

The female branch connector 6 is shown in detail in Figures 2 through 5 and is easily assembled and installed into a cable network without the need for special tools or skills. In general, the female branch connector 6 includes a housing assembly 14, a pair of terminal assemblies 16 and 17, and a signal transmission contact assembly 18. The housing assembly 14 is described in more detail below and generally comprises an elongated molded plastic housing 30 having a central cavity portion 31 for receiving and holding the signal transmission contact assembly 18 and a ground contact 19, and a pair of end portions 32 and 33 for receiving and holding the terminal assemblies 16 and 17, respectively, when the connector is assembled.

The connector assemblies 16 and 17 are identical to each other and the same reference numerals are used to describe their construction. Each connector assembly includes a molded plastic, helical fitting 41 having an electrically conductive member 42 attached thereto. A central passage 43 extends axially through the fitting 41 and an inner shoulder 44 of the passage separates the passage into a first passage portion 43a and a second passage portion 43b of reduced diameter. The conductive member 42 is a relatively thin metal member shaped to form a sleeve portion 46 and a flange portion 47. The sleeve and flange portions have a central opening 49 extending therethrough which is alignable with the passage 43 in the fitting 41 when the two components are assembled. More particularly, as best shown in Figs. 3-5, the conductive member 42 is attached to the connector 41 by inserting the sleeve portion 46 into the passage 43 until the flange portion 47 contacts the end surface 51 of the connector 41. After insertion, the end of the sleeve portion 46 extending into the passage portion 43a is flared outwardly as shown at 46a in Figs. 3-5 using a suitable tool to thereby secure the conductive member 42 to the connector so as to allow the conductive member free rotational movement relative to the connector.

The connector assemblies 16 and 17 formed in this way include clamping elements and are designed to receive the ends of the cables 12a and 12b, respectively. Before inserting the cables into the connectors, the cables are prepared by by cutting and removing a length of their outer dielectric jacket 21 to expose a portion of the conductive braided sheath 22 therein. In addition, a smaller portion of the conductive jacket is removed to expose the inner dielectric sheath 23. The cables thus prepared are then inserted from the ends 52 of the connectors 41 into and through the passages 43 of the connectors 41 and through the openings 49 in the conductive elements 42. The insertion of the cables is limited by the abutment of their outer jackets 21 against the flared portions 46a of the sleeve 46; however, the conductive sheaths 22, the dielectric sheath 23 and the center conductors 24 extend completely through openings 49. After passing through the terminal assemblies, the exposed conductive outer sheaths 22 are then fanned out over the outer surfaces 53 of the radially extending flange portions 47 of the conductive members 42 in the manner shown at 22a, thereby completing assembly of the cables to the terminal assemblies. As will be explained below, the surfaces 53 serve as first sheath engagement surfaces or clamping surfaces for clamping the conductive sheaths to the receptacle connector 6.

Each fitting 41 includes an outer threaded surface area 56 for engaging the housing assembly 14 and a ribbed area 57 for providing an improved gripping surface for the worker to assist in inserting the fitting assemblies into the housing assembly.

The connector assemblies 16 and 17 are insertable into and secured to end portions 32 and 33 of the housing 30, respectively. The end portions 32 and 33 define recesses 71 and 72, respectively, which have internal threads for securing to the threaded portions 56 of the connector assemblies 16 and 17, respectively. The recesses 71 and 72 have rear walls 74 and 75, respectively, with small central openings 76 and 77 (mol-%3) therein for receiving the center conductors 24 of the cables and their insulating jacket 23, as shown in mol-%4 and 5. The housing is molded from an insulating plastic material and defines narrow slots 81 and 82 extending into cavities 71 and 72, respectively, near rear walls 74 and 75 of the housing. These slots are designed to receive plate-like portions 91 and 92 of a grounding contact 19. Outer surfaces 93 and 94 of plate-like portions 91 and 92, respectively, define second sheath engaging surfaces or clamping surfaces that clamp against first sheath engaging surfaces 53 on flange portions 47 of conductive members 42 to clamp flared portions 22a of outer conductive sheaths 22 therebetween when terminal assemblies 16 and 17 are mounted to housing assembly 14. The plate-like areas 91 and 92 include central openings 90 and 95 for receiving the center conductors 24 and their insulating sheaths 23 when inserting the cables into the housing assembly 14.

As best shown in Fig. 3, the plate-like portions 91 and 92 of the ground contact 19 have a dome-shaped, resilient spring configuration for providing stored spring force to compensate for any deformation or creep of the plastic components when the terminal assemblies 16 and 17 are screwed into the ends 32 and 33 of the housing 19. In addition, the grounding contact has a central strip 98 connecting the plate-like ends 91 and 92 together and a central ground bar 99 disposed at right angles along one side of the strip. The grounding contact is secured to the housing by four bosses 96 on the central strip (Fig. 2) which are pressed into the inner surfaces of the sides of the molded housing 30. Spring fingers 97 may also be provided on the central ground bar 99 for engaging a surface on the housing 30 to thereby further lock the grounding contact to the housing after the grounding contact has been inserted into the housing.

When the grounding contact 19 is inserted into the housing 13, the dome-like plate-shaped portions 91 and 92 extend into the slots 81 and 82, respectively, so that the plate-like portions 91 and 92 are positioned within the cavities 71 and 72 adjacent to the rear walls 74 and 75 thereof, respectively. The central grounding bar 99 extends through a slot 100 formed in the side of the housing 30.

To assemble the female connector 6, the grounding contact 19 is first inserted into the housing 30. Thereafter, the terminal assemblies 16 and 17, to which the ends of the cables 12a and 12b are attached, respectively, are screwed into the ends 32 and 33 of the housing 30. The fanned-out braid portions 22a of the outer sheaths 22 are clamped between the sheath engagement surfaces 53 on the contact elements 47 and the cover engagement surfaces 93 and 94 are sandwiched between the plate-like portions 91 and 92. When the connector assemblies are screwed to the housing, the dome-shaped plate-like portions 91 and 92 compress in a manner similar to a Bellville washer, with the portions 91 and 92 being able to spring back by spring action to an extent necessary to compensate for movement due to plastic creep of the screwed plastic elements. The conductive covers of the cables are thereby firmly clamped to the connector and electrically connected to the ground contact 19 located therein.

The second clamping surfaces 93 and 94 on the plate-like areas 91 and 92 are preferably roughened in order to clamp the fanned-out conductive sheaths 22a more firmly thereagainst. Such roughened surfaces can be, for example, a plurality of raised ridges or depressions on the surfaces. For the purpose of illustration,

Fig. 3 (in section) a plurality of annular ribs 151 on the clamping surface 93 and a plurality of radial ribs 152 on the clamping surface 94.

When the connector assemblies 16 and 17 are screwed into the housing 30, the dielectrically coated but deshielded signal-carrying center conductors 24 of the cables 12a and 12b are inserted through the openings 90 and 95 in the plate-like areas 91 and 92 of the grounding contact and into the central cavity area 31 of the housing 30. The cables thus also serve to hold the grounding contact 19 in the housing 30 when the socket-like connector is fully assembled. The encased center conductors extend over U-shaped rib structures 101 and 102 formed in the central region 31 which support the encased center conductors and serve as support means for connecting the center conductors to signal transmission contact elements as will be explained below. A centrally located wall 106 extends through the central cavity region 31 and serves as a stop and dielectric barrier to ensure that the center conductors entering the central region of the housing from opposite sides do not inadvertently contact one another. The housing assembly 14 is now ready to receive the signal transmission contact assembly 18.

The signal transmission contact assembly 18 includes a contact housing 121 made of molded plastic material and a pair of signal transmission contacts 122 and 123 held in the housing.

The signal transmission contacts 122 and 123 each include downwardly extending U-shaped portions defining a slot means 131 consisting of first and second slots 131a and 131b formed in the two sides of the U-shaped portions for receiving the exposed insulating layers 23 of the cables 12a and 12b. Tapered portions 133 at the bottom of each slot guide the insulating layers 23 into the slots and the edges 132 thereof have cutting edges for cutting through the insulating layer 23 when the contact assembly 18 is inserted into the housing 30 to provide direct electrical contact between the center conductors 24 of the cables 12a and 12b and the contacts 122 and 123, respectively. When the contact assembly 18 is fully inserted into the housing 30, the center conductors 24 extend through narrow slot portions 134a and 134b of the slots 131a and 131b to firmly clamp the conductors 24 and reliably establish electrical contact between the contacts and the center conductors (see Figs. 8 and 9). The insulation displacement type contacts used herein are known in the art and are disclosed, for example, in U.S. Patent No. 3,617,983.

At the upper ends of the signal transmission contacts 122 and 123 opposite the slot means 131 there is a normally closed switch means 140 extending at a right angle along one side of the contacts and defined by switch arms 141 and 142. The switch arm 141 is fixed to the contact 122 while the longer switch arm 142 is movable with respect to the contact 123. The switch means 140 is designed to provide a first signal path between the signal transmission contacts 122 and 123 and thus between the signal-carrying conductors 24 of the cables 12a and 12b.

The switch arms 141 and 142 have elongated bump features 161 and 162 near their outer tips. The bump features 161 and 162 are oriented perpendicular to each other to form a cross-contact configuration when the switch arms are in contact with each other. The movable switch arm 142 is preferably biased such that when mounted in the contact housing, the movable arm 142 is in a slightly bent condition, to ensure a firm, reliable electrical connection of the switch arms.

The signal transmission contacts 122 and 123 further include planar regions 163 and 164 that are continuations of the U-shaped regions. The planar regions 162 and 164 define connection regions for contact terminals included in the complementary plug-type connector 8, as will be explained below. As best seen in Figs. 4 and 5, the molding features 171 and 172 on the contact housing 121 provide support for the signal transmission contacts, and arcuate curved contact regions 173 and 174 between the respective planar and U-shaped regions of the contacts press against the contact housing molding features to thereby provide support while the insulation displacement connection to the cables takes place.

The insulation displacement connection occurs when the signal transmission contact housing assembly 18 is inserted into the central cavity of the connector housing 30. As the contact assembly 18 is inserted, the center conductors of the cables are received within the tapered portions 133 of the slot means 131 of the contacts. As insertion continues, the cutting edges 132 cut through the protective covers 23 of the cables, thus allowing the exposed center conductors of the cables to enter the narrow portions 134a and 134b of the slots to electrically connect the center conductors to the contacts. The seating portions 101 and 102 in the connector housing 30 and the molding portions 171 and 172 in the signal transmission contact housing 121 provide a supportive hold during cutting of the insulating layer of the cable. The size of the narrow slot areas 134a and 134b is such that the center conductor wires 24 are firmly and reliably retained therein; even greater reliability is achieved by forming slots in the two sides of each U-shaped contact. When the signal transfer contact housing is inserted into the connector housing, the center ground bar 99 of the ground contact 19 is received in a tapered slot 105 in the signal transfer contact housing, as best shown in Figs. 6 and 7.

The signal transmission contact housing 121 includes passive locking features 126 on its four lowermost corners positioned to engage protrusions 125 on the connector housing 30, and active locking features 127 on each of its sides for cooperating with locking features 128 on the housing 30 to secure the contact assembly 18 in the connector housing 30.

When the signal transmission contact arrangement 18 is inserted into the housing arrangement 14, the assembly of the female branch connector 6 and its connection to the cables 12a and 12b is completed. When the female branch connector is not used to make a branch connection in the cable network, the switch arms 141 and 142 are in contact with each other and the switch device 140 is closed, as shown in Fig. 8, to provide a first signal path within the female branch connector housing between the signal transmission contacts 122 and 123 and thus between the center conductors 24 of the cables 12a and 12b. In a corresponding manner, the outer conductive sheaths of the cables 12a and 12b are connected to the earth contact 19.

To provide a branch connection in the cable network, the plug-type connector 8 is inserted into a recess or cavity 175 in the signal transmission contact housing 121 of the socket-type branch connector 6. The plug-type connector 8 is connected to an electrical cable 176 which includes a conductive jacket 177, a pair of signal-carrying conductors 183 and 184 surrounded by insulation, and a third conductor 182 surrounded by insulation. The conductors 182, 183, 184 include respective conductive regions 182', 183', 184' which are connected to respective conductive terminals 186, 187, 188, each of the terminals having a knife-like configuration of the type disclosed in U.S. Patent No. 2,791,755. The terminals 186, 187, 188 are attached to an outer surface of an insulating housing 181 of the plug 8 and are aligned on the housing 181 such that they face the signal transmission contacts 122, 123 and the ground bar 99 of the ground contact 19, respectively. At least a portion of the plug 8 and the terminals 186' 187, 188 are designed for releasable insertion into a plug receiving opening or recess 175 of the contact housing 121. During this insertion process, the housing 181 of the plug 8 acts on the connection 186 in such a way that the latter engages the grounding bar 99 in a compressive manner and slides against it in order to electrically connect the conductive sheath 177 of the plug 8 with the conductive sheaths 22 of the cable 12a and 12b. (see Figs. 6 and 7). During this insertion process, the housing 181 of the plug 8 also urges the terminals 187 and 188 so that they compressively engage and slidably impinge on the flat surfaces 163 and 164, respectively, of the signal transmission contacts 122 and 123, in order to thereby establish a second signal path between the first and second signal transmission contacts via the plug 8 (see Figs. 4 and 5). The cables 182, 183, 184 are held in the housing 181 of the plug-type connector by means of known glands 191, 192 and 193.

The plug connector 8 includes a locking member 201 having a portion 207 designed to engage a locking surface 202 in the contact housing 18 when the plug connector is inserted into the socket connector, thereby retaining the connectors in the mated condition (see Figures 6, 7 and 10). The locking member 201 includes an extended finger portion 203 that allows the plug connector to be easily disengaged from the socket connector when desired. Extended ribs 211 and 212 formed in the contact housing 121 aid in the mating process when the plug connector is inserted into the plug receiving cavity 175 of the contact housing.

The housing 181 of the plug-type connector is configured such that a control surface 205 (see Figs. 9 and 10) is defined at its lower outer corner. The control surface 205 is adapted to engage the movable switch arm 142 during interconnection of the connectors and designed to release the switch arm 142 from the switch arm 141 to interrupt the first signal path between the signal transmission contacts 122 and 123. More specifically, in connecting the connectors together, the ground connection is first made between the central ground contact bar 99 and the ground contact terminal 186 of the plug-type connector to connect the conductive sheaths in the cables 12a and 12b to the ground cable 182. Further insertion of the plug-type connector into the cavity 175 causes the signal transmission contacts 187 and 188 of the plug-type connector to engage the flat areas 163 and 164 on the contacts 122 and 123, momentarily creating a dual signal path through both the normally closed switch device 140 and the plug-type connector. However, as the plug connector is further inserted and finally seated, the control surface 205 is caused to move the movable switch arm 142 away from the switch arm 141, thereby opening the switch assembly 140 and leaving only a series connection of the cables 12a and 12b through the plug connector into the work station device (not shown) connected to the plug connector. Of course, if the plug connector is detached from the socket connector, the movable switch arm 142 is thereby released from the control surface 205 and automatically returns to contact with the switch arm 141 to close the switch assembly 140 and restore the first signal path between the signal transmission contacts 122 and 123.

The present invention thus provides a branch connector assembly that maintains network integrity on all sides. The assembly includes a female branch connector mountable in a coaxial cable network that provides a first electrical signal path between two cables when the branch connection is not in use. The assembly further includes a male connector matable with the female branch connector and, when mated, interrupts the first signal path after establishing a second signal path between the two cables via the male connector and an external device connected thereto, thereby establishing a series connection of the external device to the network.

The connector assembly is manufactured primarily from stamped and formed metal strip material and molded plastic material, rather than from precision machined parts, resulting in a connector that is less expensive and can be manufactured in high volume.

It is to be understood that the invention may take many other forms. Thus, it is to be understood that the invention is to be limited only as necessary within the scope of the following claims.

Claims (8)

1. A branch connector assembly (10) comprising a housing (14), a conductive grounding contact (19) carried by the housing (14) for connection to corresponding conductive sheaths (22, 23) of a first and a second electrical cable (12a, 12b), first and a second signal transmission contact (122, 123) carried by the housing (14) for connection to corresponding signal-carrying conductors (24, 24) of the first and the second electrical cable (12a, 12b), wherein portions (141, 142) of the first and the second signal transmission contact (122, 123) are electrically connected to one another, and a plug (8) connected to a third electrical cable (176), wherein the plug has corresponding conductive electrical terminals (186, 187, 188) for connection to the respective conductors (182, 183, 184) of the third electrical cable (176) and wherein the housing (14) has a cavity (175) for receiving the plug (8), characterized in that the areas (141, 142) of the first and second signal transmission contacts (122, 123) form a normally closed switch (140), that the electrical connections (186, 187, 188) of the plug (8) include two signal transmission connections (187, 188) which are connected to two signal-carrying conductors (183, 184) of the third electrical cable (176), and that the plug (8) is designed to be received in the cavity (175) in order to have a ground connection (186) of the plug (8) to the ground contact (19) carried by the housing (14) and to connect each of the signal transmission terminals (187' 188) of the plug (8) to a corresponding signal transmission contact of the signal transmission contacts (122, 123) carried by the housing (14) and to engage the plug (8) with the switch (140) and to separate the regions (141, 142) of the signal transmission contacts (122, 123) forming the switch (140) from one another. 2. Tap connector arrangement (10) according to claim 1, characterized in that a first and a second clamping element (16, 17) are attached to the housing (14) for clamping the conductive sheaths (22' 22) of the first and the second cable (12a, 12b) against the ground contact (19). 3. A tap connector assembly (10) according to claim 2, characterized in that the first and second clamping elements (16, 17) include first and second conductive elements (42, 42) and sheath engagement surfaces (53, 53) and the grounding contact (19) includes a pair of sheath engagement surfaces (93' 94). 4. Branch connector assembly (10) according to claim 3, characterized in that the first and second clamping elements (16, 17) have a first and a second connector (41, 41) with an axial passage (43, 43) for receiving the first and the second cable (12a, 12b), respectively, and that the housing (14) has openings (76' 77) which, when the first and second connectors (41, 41) are attached to the housing (14), are in communication with the passages (43, 43) in the first and second connectors (41, 41). 5. Branch connector arrangement (10) according to claim 4, characterized in that the envelope engagement surfaces (53, 53, 93, 94) of the connecting pieces (41, 41) and of the grounding contact (19) are essentially plate-shaped surfaces. 6. Tap connector assembly (10) according to claim 4, characterized in that the connecting pieces (41, 41) are attached to the housing (14) by threaded engagement. 7. Branch connector assembly (10) according to claim 1, characterized in that the first and second signal transmission contacts (122, 123) are insulation-displacing contacts. 8. Tap connector assembly (10) according to claim 1, characterized in that a movable switch arm (142) is part of one of the signal transmission contacts and is displaced by the plug (8) to open the normally closed switch (140).