Such junction boxes are also fully accessible to service personnel of the telephone company after installation.

One such network interface device is disclosed in U. S.

Patent No. 4,979,209 for a plurality of subscribers, wherein an enclosure includes a primary lid extending over the entire enclosure and securable by service personnel, and a secondary lid over the subscriber- accessible portion of the enclosure securable by the subscribers; such enclosures commonly provide access to the subscriber-accessible portion by service personnel but the subscriber-accessible portion remains secured against unauthorized person. Individual modules within the subscriber-accessible portion are disclosed to include individual security covers such that each subscriber module is secured against access by the other subscribers.

In U. S. Patent No. 5,420,920 there is disclosed a subscriber module having a test port or jack in which pairs of contacts are interconnected by a dedicated plug inserted thereinto to complete circuits between the telephone cable and the premises wiring for regular in- service use. When the dedicated plug is removed during an investigation of a fault, another plug joined to a telephone unit is insertable by the subscriber to again complete the circuits to determine the presence or absence of a fault in the telephone company wiring. The dedicated plug of the module is adapted to seal the jack cavity when in position, protecting the contacts exposed in the jack, and is joined to the module by a lanyard when removed from the jack. Conductors of the premise

wiring are easily terminatable by insulation displacement techniques to terminals using a stuffer cap, with the terminals connected to first contacts of the jack contact pairs by circuit board traces, while second contacts of the pairs are connected by other board traces to conductors connected to the distribution cable.

A problem exists in that a simplified wire termination is needed. Additionally, it is desirable to be able to seal such a simplified termination.

The present invention employs a device that allows for wire insertion or loading from opposing ends of a pivotal stuffer member, and provision for a separate sealant means that can be incorporated into the device.

The manner by which this can be achieved will become apparent in the specification which follows, particularly when read in conjunction with the accompanying drawings.

The present invention is directed toward a power tap connector of the type for terminating by insulation displacement a pair of conductors. The connector includes a housing for receiving at least a pair of upstanding IDC terminals. A pivotally mounted wire carrier has front and rear faces arranged on the housing. The wire carrier is pivotal from a first conductor unterminated position to a second conductor terminated position. The wire carrier having a conductor receiving opening extending from the front face to the rear face for each the IDC terminal. An IDC terminal receiving slot is in communication with each said opening. Whereby an insulated conductor may be positioned for termination to a corresponding IDC terminal within the opening by entry thereto through either the front face or the rear face.

Embodiments of the present invention will now be described by way of example with reference to the accompanying drawings, in which: FIGURE 1 is a bottom perspective view of an exemplary four position power tap network connector according to this invention, where the two left modules illustrating a terminated position, less wires, the right module representing the wire receiving or unterminated position, and the intermediate module showing the components thereof in an exploded position; FIGURE 2 is a perspective view of the pivotal stuffer member for mounting in the connector housing; FIGURE 3 is a top perspective view of the connector housing of a typical four position power tap network connector according to this invention; FIGURE 4 is a bottom perspective view of the connector housing of FIGURE 3; FIGURE 5 and 6, respectively, are top and bottom perspective views showing a pair of insulated conductors positioned for IDC termination therewithin; FIGURE 7 is a sectional view taken longitudinally through the wired module of Figures 5 and 6; FIGURE 8 is a sectional view, similar to FIGURE 7, showing the IDC terminated position; FIGURE 9 is a top view of the four position power tap connector of this invention, modified with a gel sealant chamber adjacent the rear end thereof; FIGURE 10 is a rear perspective view of a second embodiment of the invention, where such embodiment is directed to a single position connector; FIGURE 11 is a front perspective view of the embodiment of FIGURE 10; FIGURE 12 is a bottom perspective view of the single position embodiment of FIGURES 10 and 11; FIGURE 13 is a front view of the second embodiment showing a preferred mounting procedure;

FIGURE 14 is a perspective view of an alternate type of terminal that may be used herein, particularly for the single position second embodiment; FIGURE 15 is a cross sectional view of an alternate embodiment of the wire carrier; and FIGURE 16 is a perspective view of the alternate embodiment of the wire carrier.

The present invention relates to a field terminated, power tap network connector 10, the elements thereof being illustrated in a first embodiment in Figure 1. The connector 10 comprises a modular housing 12, with each modular unit thereof adapted to receive a pair of IDC terminals 14, and a wire carrier 16 arranged for pivotal movement on the housing 12.

The modular housing 12, where four units are illustrated in the top and bottom perspective views of Figures 2 and 3, respectively, comprises a base 18 having upstanding end or intermediate walls 20 to separate the respective modular units. The modular housing further includes a segmented front wall 22 (Figures 1 and 3), where such wall segments terminate the respective intermediate or end walls 20. Such segmented front walls 22 include an inwardly facing shoulder 24 having an arcuate face 26 ending in a stop 28, which as will be apparent in the later description, that defines the pivotal arc or path of movement for the pivotally mounted wire carrier 16. Further, the_ respective walls 20, adjacent the shoulder 24, include a recess 29 to receive a cam guide, as described hereinafter, on the sides of the pivotal wire carrier.

The rear of the housing 12, as best seen in Figures 3,4,5 and 7 includes an opening 30, where such opening is defined by the respective walls 20, floor 32 of base 18, and a rear wall segment 34 which acts as a complementary pivot member. The significance of the opening 30 will become apparent hereinafter. Finally, the housing 12, through its base 18, is provided with

plural terminal slots 36 for receipt of the IDC terminal 14 shown in Figure 1.

The IDC terminal, illustrated as poised for entry into the housing base 18 in Figure 1, consists of a stamped metal contact having a pair of IDC split beam legs 40, a solder tail 42, and a shoulder 44 defining the two portions. In the assembly of the connector, with the plane of the legs longitudinally arranged, the solder tail 42 is press fit into and seated within a respective slot 36, with the ends 46 projecting below the base. In this position the housing may be mounted on a suitable planar electronic device, such as a printed circuit board, and the terminal ends 46 soldered to appropriate circuit carrying plated through holes in the device.

The wire carrier 16, illustrated in the isolated position in Figures 1 and 2, comprises a body portion having an essentially flat front face 50, a curved rear face 52 which acts as a pivot member, and a pair of through openings 54, extending between the respective faces, for receiving a pair of wires, i. e. power and ground or tip and ring, for example. Communicating with said openings 54, through the bottom wall 56 thereof, are a pair of slots 58, typically offset from one another, for receiving the split beam legs 40 during termination of the subscriber wires, see Figure 1. To effect pivoting or arcuate movement of wire carrier 16, the rear face 52 is made semicylindrical and sized to pivotally move within the opening 30 under the rear wall segment 34. Toward the front face 50, along each side 60, a cam follower 62 is provided to seat within the recess 29 during the pivoting movement of the wire carrier 16. Finally, the wire carrier may be provided with a forward flanged portion 64 to facilitate movement, particularly during untermination of the system, of the wire carrier 16.

Figures 5 to 8 illustrate a unique feature of this invention, namely the accessibility of loading the power

and ground wires or the tip and ring wires"W", or some other type of premise wiring, for example, from either the front face 50 or rear face 52. Figures 7 and 8 show sequentially the termination of the wires"WII. Figure 7 shows the wire carrier 16 in the first or wire insertion position in which the wires may be loaded into the wire carrier. Once the wires are loaded into the wire carrier 16, with the slots 58 overriding the respective legs 40 of the IDC terminals 14, the wire carrier 16 is pivoted downwardly such that the bottom wall 56 thereof rests against the housing floor 32. This is the second or wire termination position. As this movement takes place, the wires''Wll are stuffed between the respective legs 40 where the insulation of the wire is displaced and the core thereof electrically contacts the walls between such legs. Simply moving or pivoting the wire carrier 16 upwardly will effect untermination of the wires"W".

When the wire carries 16 is in the unterminated position, the cam guide 62 is above the walls 20 and provides resistance against downward movement of the wire carrier. A front shoulder 61 of the wire carrier (see Figure 2) abuts against the stop 28 thereby preventing the wire carrier from being rotated into a more vertical position. When the wire carrier 16 is pushed into the terminated position, the cam guide 62 is pushed down until it resides within the recess 29 thereby securing the wire carrier in the terminated position. The cam guide 62 provides enough resistance to the wire carrier to keep it in the desired position, however, it allows the wire carrier to be easily moved by the operator using only his hands.

The power tap connector illustrated is specifically designed to provide a connection for the power conductors on a coax cable. The signal and power from the coax cable are split in a tap utility box on the utility pole and they are separately sent to the customer's home to provide both the signal to the home

and also the power to operate the customer's box. The power from the coax cable is directed through the circuit board upon which the power tap connector is mounted and connected to the solder tails 42. Since the tap box is mounted on a utility pole, it must be protected from the weather. In order to accomplish this, it is necessary to seal the exit points for the power wires.

One of the advantages of this dual loading system of the present invention is illustrated in Figure 9.

Here, a reservoir 70, containing a semi-fluid, self- healing gel, such as a hydrocarbon based sealant, may be incorporated. Figure 9 represents the tap box. The reservoir 70 is in the wall of the tap box through which the power wires will extend. The power tap connector will be mounted on the inside of the box along an outer wall of the box and the wires will extend through the walls and through the reservoir 70. A gel suitable for practicing this invention is described in U. S. Patent No. 5,360,350. The nature of this type of gel allows loading of the wires"W"initially through the gel, then into the wire carrier 16 through the rear face 52. By placing the gel reservoir 70 adjacent the pivoting rear face 52, there is little disturbance about the wires"W" and that the self-healing nature of the gel maintains an effective seal thereabout. Were the reservoir placed adjacent the opposite end of the wire carrier, one can see that the gel would be disturbed significantly during termination and untermination thereby effecting its ability to seal the wires.

Figures 10 to 14 illustrate a second embodiment, which is distinguishable from the earlier embodiment by the use of a single power tap connector 80, and by the use of a modified IDC type terminal 82, see Figure 14.

Specifically, the single power tap connector 80 includes a housing 84 having a pair of spaced apart transverse walls 86 between which is a pivotally mounted wire carrier 88, constructed in a manner described above.

The housing 84 further includes lateral extensions 90, with through holes 92 therein, for mounting to an underlying board or panel, for example, see Figure 13.

Extending below the housing is a contact receiving extension 94, where such extension includes a cavity dividing wall 96. Note in Figure 12, an underside perspective view, that a pair of contact receiving cavities 98 are found.

The preferred type of male terminal 82 to be used herein is illustrated in Figure 14. Such male terminal 82 includes an IDC slotted beam 100 at one end thereof, and a flat bladed end 102. For securing same into the housing 84, a lance 104 may be struck therefrom for latching engagement in the housing. A typical female or complementary contact 106 is illustrated in Figure 12.

Briefly, the contact 106 includes a pair of inwardly turned arms 108 for engagement with the bladed end 102.

For a more detailed discussion of such complementary contacts, reference is made to U. S. Patent No.

2,774,951, assigned to the assignee hereof, where the contents thereof are incorporated herein by reference.

This single power tap connector offers the same unique advantages as noted above, that is, the wire carrier 88 may be loaded from either the front face, or the rear pivoting face. The single power tap connector is typically mounted in the customer's home to provide the connection of the power wires from the utility tap box which is mounted on the utility pole.

Figure 15 and 16 show an alternate embodiment of the wire carrier 110. The wire carrier 110 is similar to wire carrier 16 in all respects except that the wire carrier 110 has a tool assist slot 112 along the upper surface 114 which extends downwardly from the top surface 114. The tool assist slot is designed to receive the head of a screw driver or a similar tool and is used to assist in the termination and untermination of the wires"W". Even though the wire carrier 110 is designed to be operated without the use of tools, there

may be circumstances in which it may be necessary or helpful to use a tool to rotate the wire carrier. The head of a tool is inserted into the tool assist slot 112 and used as a lever to rotate the wire carrier either upward or downward and thereby terminate or unterminate the wires"WII.

The advantages of the present invention are that the power tap connector can be mounted in such a manner that the tap box can be sealed from the elements.

Further, the power tap connector allows the wires to be terminated and unterminated without the use of tools.

Further, the power tap connector has been specifically described for electrically connecting power wires, but it can be equally applicable for connecting signal wires of the telephone system such as tip and ring lines.

The power tap connector of the present invention and many of the attendant advantages will be understood from the foregoing description. It is apparent that various changes may be made in the form, construction, and arrangement of parts thereof without departing from the spirit or scope of the invention, or sacrificing all of its material advantages.