GB2398183A

GB2398183A - Sealed cable port

Info

Publication number: GB2398183A
Application number: GB0329377A
Authority: GB
Inventors: Christopher John Kissane
Original assignee: TIMEGUARD Ltd
Current assignee: TIMEGUARD Ltd
Priority date: 2002-12-19
Filing date: 2003-12-18
Publication date: 2004-08-11
Anticipated expiration: 2023-12-18
Also published as: DE60317621T2; GB0229575D0; EP1432080B1; GB0329377D0; DE60317621D1; EP1432080A1; ES2295526T3; PT1432080E; GB2398183B

Abstract

A twin-socket electrical connector has a lid 6 that closes onto a frame of a mounting box 3 to define a watertight enclosure for its sockets and any plug engaged with them. A cable from an engaged plug exits the enclosure through a respective port 15 which otherwise seals watertightly by labyrinthian seal between resilient blocks 24,25 that are carried by the lid 6 and frame in front of upper and lower resilient strips 19,20. The lower strip 20 has a slot through which the cable exits, and conforms sealingly with the sides of the cable, whereas the blocks 24,25 conform sealingly with it top and bottom, so that watertight integrity is maintained. A lever, which operates an isolating switch, may be present and may also bear on the lid 6 to block it opening when the switch is 'ON', but is moved clear of the lid 6 when the switch is 'OFF'.

Description

2398 1 83 Electrical Connectors This invention relates to electrical

connectors.

The invention is particularly concerned with electrical connectors that have sealing against ingress of water.

A twin-socket electrical connector that provides a watertight enclosure for the sockets and any plugs engaged with them, is known from GB-A2366096. The integrity of the watertight sealing of the enclosure is maintained at ports where cables from the plugs exit the enclosure, and in this respect, each port includes a pair of grooved, resilient elements which when brought together with their grooves mutually aligned define a conical passageway for tight fitting to the cable. These elements are located in the port in front of another pair of resilient elements that maintain the watertight seal by abutment with one another face to face, when there is no exiting cable.

It is an object of the present invention to provide an electrical connector of improved form in regard to maintenance of watertight sealing at a cable-port.

According to the present invention there is provided an electrical connector having a lid that closes upon a body-part of the connector to define an enclosure with sealing between the lid and body-part against ingress of water into the enclosure, wherein a cable-port for enabling an electrical cable to exit the enclosure between the lid and the body-part involves first resilient sealing-means that comprises a pair of first resilient elements which are carried by the lid and body- part respectively and which have surfaces that bear conformably and sealingly upon one another when the lid is closed, one of the pair of first elements being slotted to receive a portion of a cable exiting the enclosure at the cable-port and to conform resiliently and sealingly to at least part of the circumference of the received cable when the lid is closed, and wherein the cable-port includes a second pair of resilient elements carried by the lid and body-part respectively, which in the absence of an exiting cable between them, bear conformably and sealingly upon one another and against the slotted element for sealing as aforesaid at the cable-port when the lid is closed, and which in the presence of a cable between them exiting the cable-port through the slotted element and with the lid closed, bear conformably and sealingly against the slotted element and also upon one another and the cable to an extent to maintain integrity of said sealing at the cable-port.

The resilient elements of the first pair of resilient elements may comprise elements that have flat faces respectively for abutting one another closely face to face when the lid is closed, and the slotting of the slotted element may open from the flat, abutting face of that element. In these circumstances one of the elements of the second pair may bridge the junction between the abutting faces of the first pair of elements so as to enhance the watertight sealing achievable.

The elements of the second pair of resilient elements may have respective faces that abut one another with a ridge of one entered in a groove of the other for compression tightly within the groove so as to establish a labyrinthian watertight seal at the junction of the second pair of elements when the lid is closed.

Furthermore, the second pair of elements may be located in front (in the sense of to the outside) of the first pair of elements at the cable-port, and may be for pressed hard into face-to-face contact with the first pair of elements so as to cover the slotting of the slotted element sealingly, when the lid is closed in the absence of an exiting cable.

An electrical connector in accordance with the present invention will now be described, by way of example, with reference to the accompanying drawings, in which: Figure 1 is a plan view of the electrical connector in accordance with the invention, with its lid removed and showing a plug engaged with one of its twin sockets; Figure 2 is a front elevation of the electrical connector, partly in section and with its lid removed, the section being taken on the line II-II of Figure 1; Figure 3 is a side elevation of the electrical connector, partly in section and with its lid closed, the section being taken on the line III-III of Figure 1; Figure 4 is a plan view of the electrical connector, with its lid locked closed by a padlock; Figure 5 is an isometric view of the lid of the electrical connector; Figure 6 is a front elevation to enlarged scale of a pair of abutting sealing-strips of the electrical connector; Figure 7 is a crosssection of the pair of sealing-strips of Figure 6 in the absence of compression on them from the lid, the cross-section being taken within a cable- port of the electrical connector and showing their abutment within the port with one of two pairs of forward sealing-blocks of the electrical connector; Figures 8 to 10 are, respectively, a plan view from above, a sectional end view and a plan view from below of the upper sealing-block of the pair of forward sealing- blocks shown in Figure 7; Figures 11 to 13 are, respectively, a plan view from above, a sectional end view and a plan view from below of the lower sealing-block of the pair of forward sealingblocks shown in Figure 7; Figure 14 is a sectional view corresponding to Figure 7 when a cable exits the cable port and the sealing-strips and the forward sealing-blocks are compressed under the lid of the electrical connector; Figure 15 is a front view of the forward sealing-blocks in the condition represented by Figure 14; and Figure 16 is a front view, partly broken away, of the sealing-strips in the condition represented by Figure 14.

The connector to be described with reference to the drawings is a twinsocket connector of a conventional three-pin 13-amp plug-and-socket connection for a mains electricity power supply.

Referring to Figures 1 and 2, the socket connector has a base plate 1 that is carried within a surrounding frame 2 of a mounting box 3. Two three-pin socket outlets 4 are located side by side on the plate 1 together with switches 5 connected to them respectively. The plate 1 may also incorporate means for residual-current detection and/or fuse protection for the two outlets 4.

As illustrated in Figures 3 to 5, to which reference will now also be made, a transparent protective lid 6 (omitted from Figures 1 and 2), is mounted on hinges (not shown) that are located towards the back of the frame 2. The hinges allow the lid 6 to be opened up from the plate 1 to afford access to the socket outlets 4, and then to be closed down over it again to establish a sealed enclosure containing the plate 1 and the outlets 4.

An electrical double-pole switch (not shown), located in the connectorbox 3, is provided for isolating the socket outlets 4 and their switches 5 from power supplied to the connector-box 3. A lever 8 for operating the switch is mounted on a spindle 7, being in this regard pivotable between an 'OFF' position as shown in chain-dotted outline in Figure 1, in which the socket outlets 4 and their switches 5 are isolated electrically, and an 'ON' position as shown in Figure 4 in which power is supplied to the switches 5 for the socket outlets 4. In its 'OFF' position, the lever 8 extends sideways of the box 3 within a cut-out 9 of the lid 6 so that the lid 6 can be freely hinged open and closed. However, when the lever 8 is pivoted into its 'ON' position with the lid 6 closed, it bears on a bottom corner 10 of the lid 6. Thus, while power is supplied to the switches 5 for the socket outlets 4, the lid 6 is held down by the lever 8 and cannot be opened. An interlock (not shown) between the lid 6 and the lever 8 ensures that the lever 8 cannot be moved into the 'ON' position while the lid 6 is open.

The lever 8 is configured such that it just passes over an upwardlyprojecting pin 11 of the lid 6 in moving to the 'ON' position, and can be locked in that position as illustrated in Figure 4 using a padlock 12. More particularly, the shackle 13 of the padlock 12 is threaded round the pin 11 to lie against a downwardly- projecting shoulder of the underside of the lever 8, so that pivotal movement of the lever 8 from the 'ON' position is blocked by abutment of the shoulder with the shackle 13 while the padlock 12 is engaged.

An effective watertight seal is formed between the lid 6 and the frame 2 when the lid 6 is held closed. Referring especially to Figures 1 to 3, the seal is formed throughout the whole periphery of the plate 1 apart from at, and between, two cable-ports 15 (only one shown fully in Figure 2) located in the front of the frame 2, by a resilient string 16 of expanded-foam rubber that is inset into a part-peripheral gutter 17 of the frame 2. When the lid 6 is closed, a bead 18 (Figure 3) on its underside presses into the string 16 throughout its full length, and two rectangular, foam-rubber strips 19 and 20 which are let into the front of the lid 6 and frame 2 respectively, close onto one another. The two strips 19 and 20, which extend along the front of the frame 2 overlapping both ports 15, are of the form illustrated in Figures 6 and 7.

The strip 20 is slotted, and has in this regard two slender V-shape slots 21 that open from its upper, flat face 22 in locations aligned in the frame 2 with the two ports 15 respectively. The lower, flat face 23 of the strip 19 is squeezed against the face 22 of the strip 20 when the lid 6 is closed so that a watertight seal is completed between the lid 6 and the frame 2 apart from at the slots 21 within the ports 15. Sealing at each port 15, however, is effected by two rectangular, resilient blocks 24 and 25 that are retained within the lid 6 and frame 2 respectively, in front (that is to say, to the outside) of the strips 19 and 20 at the respective port 15.

The blocks 24 and 25, as illustrated in Figures 8 to 10 and 11 to 13, respectively, are hollow mouldings of very soft rubber. The lower face 26 of the block 24, which closes onto the upper face 27 of the block 25 when the lid 6 is closed, is flat with a rectangular projecting ridge 28 running lengthwise and centrally of it. The upper face 27 of the block 25 is correspondingly flat but in this case has a rectangular groove 29 which runs lengthwise and centrally for receiving the ridge 28 when the block 24 closes onto the block 25. When the flats of faces 26 and 27 close onto one another, the ridge 28 is squeezed against the bottom of the groove 29 so that a labyrinthian, watertight seal is created throughout the junction between the blocks 24 and 25 at the port 15.

The lid 6 is secured closed and held tightly down by operation of a snapin clip 30 (Figure 5) that engages the frame 2. While the clip 30 is in its operated - condition, the blocks 24 and 25 at each port 15 are compressed tightly onto one another throughout the faces 26 and 27, including at the ridge 28 within the groove 29. Under this compression, the rear face 31 of each block 24 is pressed hard against the front faces 32 and 33 of the strips 19 and 20 respectively, and the rear face 34 of each block 25 is pressed hard against the face 33 of the strip 20. The block 24 accordingly bridges the junction of the abutting faces 22 and 23 of the strips 19 and 20, and together with the block 25 serves to provide a resilient seal giving forward cover of the slot 21 of the respective port 15. The integrity of the overall watertight sealing of the enclosure containing the plate 1 with its socket outlets 4, is as a result maintained at each port 15.

The integrity of the watertight sealing is maintained when plugs such as the plug 35 shown in Figure 1, are engaged with either or both of the socket outlets 4.

More particularly, the ports 15 allow the lid 6 to be closed onto any exiting cable, such as the cable 36 of the plug 35, without loss of watertight seal. When, in this regard, the lid 6 is opened and the plug 35 is inserted in the socket outlet 4, the cable 36 is laid to exit the connector via the aligned port 15. More particularly, the cable 36 is laid within the slot 21 of that port 15 and across the face 27 of the block 25 in front of it.

Closing the lid 6 and holding it closed by means of operation of the clip 30, sandwiches the cable 36 between the blocks 24 and 25 of the respective port 15 as illustrated in Figure 14. Because of their resilience, the blocks 24 and 25 conform closely to the cable cross section, being squeezed onto the cable-surface for watertight sealing with it throughout a sector of the cable-surface of substantial angular extent both top and bottom, as illustrated in Figure 15. However, the squeezing of the blocks 24 and 25 onto the cable-surface top and bottom, causes them to bulge away from it leaving a cusp-shape gap 37, either side of the cable 36.

The breaching of the overall watertight seal that would otherwise result from the gaps 37 at the port 15, however, is prevented by sealing with the cable-surface where the cable 36 lies within slot 21 of the strip 20, behind the blocks 24 and 25. In this regard, the V-shape of the slot 21 ensures that throughout a substantial range of variation of cablediameter, the strip 20 when compressed under the strip 19, conforms closely to the cable cross-section. More especially, the squeezing of the strip 20 causes it to press hard against the cable- surface to establish watertight sealing with it throughout a sector of substantial angular extent either side of the cable 36, as illustrated in Figure 16. Gaps 38 and 39 nonetheless remain, but because the slot 21 is substantially vertical they are confined to regions above and below the cable 36. This is in contrast to the location of the gaps 37 which, because the junction between the blocks 24 and 25 is substantially horizontal, are confined to regions either side of it.

Thus, the gaps 37 either side of the cable 36 where it is sandwiched between the blocks 24 and 25 within the port 15, are closed off immediately behind, by the strip 20 where it conforms closely with either side of the cable 36 within the slot 21. The gaps 38 and 39 that remain top and bottom within the slot 21 are out of register with the gaps 37, so there can be no direct leakage through the gaps 37 into the gaps 38 and 39, and they are themselves closed off from the front by the top and bottom sectors throughout which the blocks 24 and 25 conform sealingly with the cable- surface. Furthermore, the pressing of the blocks 24 and 25 on the strips 19 and 20, precludes leakage via the interface between the face 33 of the strip 20 and the faces 31 and 34 of the blocks 24 and 25. The integrity of watertight sealing is accordingly maintained.

Opening of the lid 6 and removal of the plug 35, and in particular removal of its cable 36 from the port 15, restores the uninterrupted face- to-face sealing of the blocks 24 and 25 when the lid 6 has been closed again and the clip 30 operated, so that fundamental watertight sealing within the port 15, is transferred back to them.

The sealing string 16, the strips 19 and 20 and the blocks 24 and 25 may all be of synthetic rubber, in particular all or some may be of a cellular nitrite or silicone rubber. The lid 6, and the frame 2 and box 3, may be of polycarbonate or polypropylene.

Claims

Claims: 1. An electrical connector having a lid that closes upon a

body-part of the connector to define an enclosure with sealing between the lid and body-part against ingress of water into the enclosure, wherein a cable- port for enabling an electrical cable to exit the enclosure between the lid and the body-part involves first resilient sealing-means that comprises a pair of first resilient elements which are carried by the lid and body- part respectively and which have surfaces that bear conformably and sealingly upon one another when the lid is closed, one of the pair of first elements being slotted to receive a portion of a cable exiting the enclosure at the cable-port and to conform resiliently and sealingly to at least part of the circumference of the received cable when the lid is closed, and wherein the cable-port includes a second pair of resilient elements carried by the lid and body-part respectively, which in the absence of an exiting cable between them, bear conformably and sealingly upon one another and against the slotted element for sealing as aforesaid at the cable-port when the lid is closed, and which in the presence of a cable between them exiting the cable-port through the slotted element and with the lid closed, bear conformably and sealingly against the slotted element and also upon one another and the cable to an extent to maintain integrity of said sealing at the cable-port.
2. An electrical connector according to Claim 1 wherein the resilient elements of said first pair comprise elements that have flat faces respectively for abutting one another closely face to face when the lid is closed, and wherein the slotting of the slotted element of said first pair opens from the flat, abutting face of that element for receiving said portion of the exiting cable.
3. An electrical connector according to Claim 2 wherein one of the elements of the second pair bridges the junction between the abutting faces of the first pair of elements.
4. An electrical connector according to any one of Claims 1 to 3 wherein the elements of the second pair of resilient elements have respective faces that abut one another with a ridge of one entered in a groove of the other for compression tightly within the groove so as to establish a labyrinthian watertight seal at the junction of the second pair of elements, when the lid is closed.
5. An electrical connector according to any one of Claims 1 to 4 wherein the second pair of elements are located in front (in the sense of to the outside) of the first pair of elements at the cable-port, and are pressed hard into face-to-face contact with the first pair of elements to cover the slotting of the slotted element sealingly when the lid is closed in the absence of an exiting cable.
6. An electrical connector according to any one of Claims 1 to 5 wherein, slotting of the slotted element extends substantially at right angles to the junction between the second pair of elements such that with an exiting cable extending through the slotting to pass between the second pair of elements, any gaps by which the second elements do not bear conformably and sealingly upon the cable when the lid is closed, are out of register with any gaps by which the slotted element does not then conform resiliently and sealingly to the whole circumference of the cable within the slotting.
7. An electrical connector according to any one of Claims 1 to 6 wherein the slotting of the slotted element is of V-shape.
8. An electrical connector according to any one of Claims 1 to 7 wherein a socket of a plug-and-socket connection is located within the enclosure, the enclosure being adapted to house a plug engaged with the socket with its connection cable exiting the enclosure via the cable-port.
9. An electrical connector according to any one of Claims 1 to 8 wherein the lid is hinged to the body-part.
10. An electrical connector according to any one of Claims 1 to 9 including a switch for selectively isolating the connector electrically, and a lever for operating the switch that is selectively pivotable between a first position in which the switch is in its ON' condition and a second position in which it is in its isolating, 'OFF' condition, the lever when in its first position obstructing opening of the lid and when in its second position being clear of the lid to allow the lid to be opened.
11. An electrical connector according to Claim 10 wherein the lever when in its first position bears down on the lid to hold it closed.
12. An electrical socket connector substantially as hereinbefore described with reference to the accompanying drawings.