There are robotic cleaning vehicles for liquid filled containers that are connected to an electrical power source by a cable. These vehicles often follow tortuous paths of travel in accomplishing their cleaning missions and this results in torsional stress building up in the cables as they twist to accommodate the motion of the vehicles. This torsional stress can be somewhat relieved if segments of the cables rotate with respect to other segments of the same cables. This can be facilitated by inserting swivel joints into the cables. However, such joints need to ensure good electrical contact between the cable segments, isolate the electrical contacts from the liquid in which the vehicles are immersed when in operation and prevent the separation of the cable segments from each other when an axial force is applied to the cable segments. It would also be helpful if the segments of a cable could be readily disconnected from each other at a location between the power source and the vehicle when the vehicle is not in operation. One approach is to effect the electrical connection between the cable segments using a classical stereo jack and socket that has been modified by the placement of an O-ring to isolate the electrical contacts from the immersion liquid. For instance, the socket and the jack can be extended to provide for a groove to accommodate an O-ring in one of them that is distal from the tip of the jack when it is inserted in the socket. Such an arrangement is inadequate to resist the axial forces typically experienced by the cable segments when there is not some other structure to isolate the joint from these axial forces. One such structure is a rigid right angle elbow that encompasses a cable segment but it does not always operate to allow relief of the torsional stress from the movement of the vehicle as efficiently as is desired.
One embodiment includes a waterproof swivel electrical cable connector comprising a first housing including a first electrical connector being rotatably connected to a second housing including a second electrical connector. A first elastomeric washer is intermediate the first housing and the second housing and providing a watertight seal between the first housing and the second housing as the first housing and first electrical connector are rotated relative to the second housing and second electrical connector.
One embodiment involves a waterproof swiveling electrical cable connector comprising two housings and an elastomeric washer. The first housing has a bore receiving a first cable having a first electrical connector, and a first annular collar. The second housing has a bore receiving a second cable having a second electrical connector, and a second annular collar. The elastomeric washer is immediately adjacent to the first annular collar and the second annular collar. The first housing and second housing are rotatable relative to one another and at least one of the first housing and second housing are rotatable to the elastomeric washer. The first electrical connector is in electrical contact with the second electrical connector such that they maintain electrical contact as they rotate relative to each other. The elastomeric washer provides a watertight seal between the first housing and the second housing as they are rotated relative to one another.
One embodiment involves a water resistant swivel electrical cable connector comprising two housings and an elastomeric washer. The first housing has a cable receiving bore and an electrical connector receiving bore within the cable receiving bore that terminates in a first annular collar. The second housing has a cable receiving bore and an electrical connector receiving bore within the cable receiving bore that terminates in a second annular collar. The elastomeric washer is positioned between the first annular collar and the second annular collar and is immediately adjacent to both. The first housing and second housing are rotatable relative to one another about an axis that passes through both of their cable receiving bores and at least one of the first annular collar and second annular collar is rotatable relative to the elastomeric washer. The elastomeric washer provides a watertight seal between the first housing and the second housing as the first housing and second housing are rotated relative to one another.
One embodiment involves a process of connecting two cable segments to form a water resistant connection that allows the cable segments to rotate relative to each other. A first electrical connector is electrically connected a to a first cable segment and inserted into an electrical connector receiving bore which terminates in a first annular collar and is located within a cable receiving bore of a first housing such that a portion of the electrical connector is adjacent to the first annular collar. The first cable segment is affixed to the first housing in a manner that forms a water resistant seal between them and resists rotational or axial movement between them. A second electrical connector is electrically connected to a second cable segment and inserted into an electrical connector receiving bore which terminates in a second annular collar and is located within a cable receiving bore of a second housing such that a portion of the electrical connector is adjacent to the second annular collar. The second cable segment is affixed to the second housing in a manner that forms a water resistant seal between them and resists rotational or axial movement between them. The first and second annular collars are caused to sandwich an elastomeric washer between them while maintaining a common axis through the cable receiving bores of the first and second housings to create a water resistant seal which is maintained when the first and second housings are rotated relative to each other about the common axis of their cable receiving bores. The first and second electrical connectors are electrically connected such that they maintain electrical connection as they are rotated relative to each other about the common axis of the cable receiving bores of the first and second housings.
One embodiment involves a cable grasping assembly having an end cap with a bore with a decreasing diameter from one end to the other, a cable holding sleeve constructed of a readily compressible material and a housing with an interior bore for accommodating a cable. The end cap has a screw thread on the interior surface of its bore and a ledge that projects inward from the interior surface of the bore adjacent to the end with the smallest diameter. The cable holding sleeve has a generally circular bore which extends over its axial length, a series of ridges which extend radially from its outer surface and which extend axially over a significant portion of its axial length and a collar at one end beyond the axial terminus of the ridges which extends radially from the outer surface of the sleeve. The housing has a series of fingers which extend from one end of the housing with gaps between them to accommodate the ridges of the cable holding sleeve and which have an axial length such that their free ends terminate at the collar of cable holding sleeve and a screw thread on the exterior surface of the housing and spaced from the free end of the fingers.
Another embodiment also involves a waterproof lockable disengaging swiveling electrical cable connector housing structure having a first housing having a cable support structure located within its bore for receiving a first electrical cable segment, a second housing having a cable support structure located within its bore for receiving having a second electrical cable segment and a locking sleeve operatively slidingly secured to the second housing and movable from a first position to a second position to lock the first housing to the second housing, such that the first housing is rotatable relative to the second housing when the locking sleeve is in the locked position.
In other embodiments the structure includes a male housing partially inserted into the bore of a female housing. Each housing has a generally cylindrical body with a cable support structure located within its bore. It also has an interior cylindrical recess to accommodate a cable grasping sleeve, with this recess being located adjacent to the end of the housing distal from the end involved in the partial insertion. Each housing has additionally has an engagement structure for engaging a reciprocal engagement structure on the other housing in such a way that the two housings are free to rotate about the cylindrical surfaces of each other when locked together via their engagement structures and a locking sleeve. It further has a mechanism for affixing an end cap over the exterior surface of the housing which is located adjacent to the end of the housing carrying the recess for a cable sealing sleeve. The structure also includes a sealing structure carried by one of the housings which establishes a water tight seal between the housings when the male is partially inserted into the female and a cable grasping sleeves seated in their recess the housings and constructed of a compressible material. The structure further includes two end caps, each with a mechanism which interacts with the mechanism on one of the housings to affix the end cap to the housing in such a way that the interior diameter of the cable grasping sleeve seated in the housing is decreased and each end cap having an aperture which aligns with the cable support structure located within the bore of its housing. The structure additionally includes a locking sleeve which is manually moveable into and out of interaction with the engagement structures of the two housings such that as a result of the interaction they are locked into engagement and in this locked configuration do not allow axial movement between the two housings.
A further aspect of the embodiments also involves a method of connecting an electrical power cable to a robotic cleaning vehicle for a liquid filled container by providing one electrical cable segment attached to the vehicle and another attached to a power source, equipping the free end of one cable with a classic stereo jack and the free end of the other cable with a classic stereo socket and inserting these free ends into the axially opposed ends of a waterproof lockable disengaging swiveling electrical cable connector housing structure described above such that the jack becomes will become seated in the socket to create two circuit paths when the housing is assembled. The method further involves affixing the end caps of the housing structure on their respective housings such that that housing's cable grasping sleeve grasps the cable segment inserted through its end cap, inserting the male housing into the female housing such that the jack affixed to one cable segment becomes will become seated in the socket affixed to the other cable segment to create two circuit paths and moving the locking sleeve to interact with the engagement structures of the two housings such that the two cable segments are securely held together against any axial force but are free to rotate with respect to each other.
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One embodiment involves constructing the sleeve 100 out of a heat shrinkable material. In this embodiment the sleeve 100 may be secured to the cable segment 42 by the application of heat.
One embodiment involves a composite cable grasping sleeve in which a cylindrical sleeve inner component is initially heat shrunk onto a cable segment and then an outer sleeve component with radial ribs like that illustrated in
In one embodiment, one or more of the elements of the housing structure 50 are fabricated from a thermoplastic material. In one embodiment the thermoplastic material is injection molded to yield one or more of the elements. In one embodiment, the housings 60 and 70, the end caps 110 and 120 and the locking sleeve 130 are fabricated from thermoplastic materials. In one embodiment the cable grasping sleeves 90 and 100 are fabricated from an elastomeric material.
In one embodiment, the housing 50 facilitates connecting cable segments 42 and 44 which run from the robotic cleaning vehicle 20 and the electrical power source 30, respectively, such that the segments 42 and 44 may rotate with respect to each other, with a water tight connection that can be submerged in the liquid in which the vehicle 20 is submerged. In one embodiment, one cable segment is terminated with a classical stereo jack and the other is provided with a classical stereo socket such that when the jack is inserted in the socket two circuit paths two circuit paths are created. These two segments 42 and 44 are inserted through apertures in the end caps 110 and 120 into the cable support structure 62 and 72 of housings 60 and 70, respectively, such that when the inner bore ends 65 and 75 are brought into contact with each other the jack seats within the socket to create two circuit paths. The end caps 110 and 120 are screwed onto their respective housings 60 and 70 and their inclined surfaces 114 and 124, respectively, cause a decrease in the diameter of the cable grasping sleeves 90 and 100 causing them to grasp the cable segments 44 and 42. The male housing 60 is partially inserted into the female housing 70 until the ends 65 and 75 of the inner bores 64 and 75 touch and the protuberances or ridge 71 of the female housing 70 seat in the detents or groove 61 of the male housing 60. The locking sleeve 130 is moved into locking position so that it covers the protuberances or ridge 71 of the female housing 70 and the protuberance which it carries seats in a detent or groove 61 in the male housing 60 through a slot in the female housing 70. The two cable segments 42 and 44 are now securely held together against axial separation force but are free to rotate with respect to each other. In one embodiment, the release tab of the locking sleeve 130 is used to disengage the protuberance of the locking sleeve from its detent 61 in the male housing 60 and the locking sleeve 130 is moved into an unlocked position so it no longer covers the protuberances or ridge 71. An axial separating force is applied which causes the protuberances or ridge 71 of the female housing 70 to be drawn out of the detents or groove 61 of the male housing 60 by their sloped rear surfaces 73 and the male housing 60 is withdrawn from the female housing 70. In this way the two cable segments 42 and 44 are separated from each other and the stereo jack is withdrawn from the stereo socket.
Referring to
First housing 330 has a first end having a plurality of fingers 339 and an opposing second end. First housing includes an annular collar 334 proximate the second end, a radial collar 336 located intermediate the first end and the second end. Radial collar 336 includes a step 337. An externally threaded portion 338 is adjacent collar 336 between the radial collar 336 and the first end. A plurality of fingers 339 extends from the first end axially toward the threaded region. The threaded portion 338 and fingers 339 cooperate with a cable grasping sleeve 460 and end cap 360 to form a cable grasping structure to firmly hold a first cable that is inserted into a cable bore 362 of the end cap 360 and a cable bore 332 of the first housing 330. First housing 330 has an external surface 319 that is intermediate radial collar 336 and annular collar 334.
An O-ring 420 cooperates with radial collar 336 to provide a water resistant seal when end cap 360 is threaded onto the first housing 330 via threads 338. An O-ring 440 seats in first housing O-ring groove 441 and cooperates with the first housing 330 when end cap 360 is threaded onto the first housing 330 via its threads 338 to provide a water resistant seal. In one embodiment O-rings 420 and 440 may be other types of elastomeric seals known in the art. First housing 330 accommodates a first electrical connector or stereo jack 370 that may have a knurled surface 371 and a radial collar 372 in in a stereo jack insertion bore 335 in a manner described hereinafter.
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A V-ring 400 is captured between the radial collar 336 and the annular end wall 321 when first housing 330 is positioned within second housing 320. Second housing 320 includes a step 326 as well as threads 327, O-ring groove 431 and fingers 328. Step 326 is located intermediate annual end wall 321 and threads 327, O-ring groove 431 is located intermediate threads 327 and fingers 328 and the threads 327 are located intermediate step 326, and fingers 328. Second housing 320 also includes protrusions 348 intermediate step 326 and threads 327 that engage detents 347 in locking sleeve annular collar 346. Each finger 328 has a free end proximate the second end of the second housing 320. Fingers 328 cooperate with a cable grasping sleeve 450 and end cap 350 to form a cable grasping structure to firmly hold any cable that is inserted into the cable bore 322 of the second housing 320. End cap 350 includes internal threads 352 that permit end cap 350 to be threadably secured to second housing 320 on threads 327. An O-ring 430 seats in the second housing O-ring groove 431 and cooperates with second housing 320 when end cap 350 is threaded onto the first housing 320 via threads 327 and the end cap's threads 352 to provide a water resistant seal. V-ring 400 and O-ring 430 may each be another type of elastomeric seal known in the art. The second housing 320 accommodates a second electrical connector or stereo jack receptacle 380 that has a knurled surface 381 and a radial collar 382 in stereo receptacle insertion bore 329 a manner described hereinafter.
A Locking sleeve 340 has fingers 344 that engage step 337 of radial collar 336 when the first housing 330 is partially inserted into the second housing 320 and the second housing 320 is inserted into the locking sleeve 340. Referring to
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Cable grasping sleeves 450 and 460 are shown as independent elements. However, they could also be features of the two cables to be joined by the cable connector. For instance, they could be elastomeric sleeves which have heat shrunk or adhesively affixed onto the cables or they could otherwise be a part of the outer structure of the cables which provides elastomeric surfaces which interact with the fingers 329 and 339 to provide a water resistant seal and resist axial movement of the cables independent of the first and second housings.
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First housing cable bore 332 ends in a stereo jack insertion bore 335. Stereo jack knurled surface 371 is positioned within bore 335 to hold the stereo jack 370 in place and coaxial to the axis of the cable connector. In a similar manner, the second housing 320 has a stereo receptacle insertion bore 329 at the end of cable bore 322. Stereo receptacle knurled surface 381 is positioned within bore 329 to hold the stereo receptacle 380 in place and coaxial to the axis of the cable connector. In an alternative embodiment stereo receptacle 380 may be retained by the first housing 330 and the stereo jack 370 retained by the second housing 320. Also the stereo jack and its receptacle could readily be replaced by any connector set which provides two independent conduction paths and is able to maintain these conduction paths when the two elements of the set are rotated relative to each other. One such approach is disclosed in European Patent No. 1,383,205, which is incorporated herein by reference.
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The cable connector 310 may be conveniently used to join two cable segments 42 and 44 by soldering the two conductors of one of the cable segments to the two conductive leads of the stereo jack 370 and the two conductors of the other cable segment to the two conductive leads of stereo jack receptacle 380. Stereo jack 370 and its attached cable segment are then threaded through end cap 360 by passing it through its cable bore 362, O-ring 420, first housing cable grasping sleeve 460 and O-ring 440 and then it is inserted into first housing 330 past first housing teeth 339 into first housing cable bore 332 until stereo jack radial collar 372 is proximate first housing cable bore step 333. This involves force fitting stereo jack knurled surface 371 into the stereo jack insertion bore 335. O-ring 420 may conveniently be seated on the end cap 360 and O-ring 440 may be seated in first housing O-ring groove 441 before the threading. Sleeve 460 may already be in place inside teeth 339, though it may be more convenient to thread the cable segment through teeth 339 before seating sleeve 460 in teeth 339. Then first housing end cap 360 is threaded onto first housing threads 338 until a water resistant seal is created between first housing end cap 360 and first housing radial collar 336 by exerting an axial force on O-ring 420. This action also creates a water resistant seal between O-ring 440 and end cap 360 and forces the fingers 339 into sleeve 460 to create a water resistant seal and a grasping force that resists axial movement between the cable segment and first housing 330.
The stereo receptacle 380 and the corresponding attached cable segment are threaded through end cap 350 by passing it through its cable bore 351, O-ring 410, locking sleeve bore 342, second housing cable grasping sleeve 450 and O-ring 430 and then it is inserted into second housing 320 past second housing teeth 328 into second housing cable bore 322 until stereo receptacle collar 382 is proximate second housing cable bore step 325. This involves force fitting stereo jack receptacle knurled surface 381 into stereo receptacle insertion bore 329. O-ring 410 may be conveniently seated in second housing O-ring groove 411 and O-ring 430 may be conveniently seated in second housing O-ring groove 431 before the threading. Sleeve 450 may already be in place inside teeth 328, though it may be more convenient to thread through teeth 328 before seating sleeve 450 in teeth 328.
Locking sleeve 340 may be placed over second housing 320 until locking sleeve annular collar 346 contacts second housing step 326 at which point locking sleeve radial slots 347 will have engaged second housing radial projections 348. The slots 347 and the projections 348 are dimensioned to frictionally engage each other. The locking sleeve 340 may be in place over second housing 320 when stereo receptacle 380 and its attached cable segment are inserted into second housing 320 or it may be moved into position over second housing 320 after the stereo receptacle 380 and its attached cable segment are passed through locking sleeve bore 342.
Then second housing cap 350 is threaded onto second housing threads 327 until it establishes a water resistant seal between itself and locking sleeve annular collar 346 by exerting an axial force on O-ring 410. This action also creates a water resistant seal between O-ring 430 and end cap 350 and forces fingers 328 into sleeve 450 to create a water resistant seal and a grasping force that resists axial movement between the cable segment and second housing 320.
The first housing 330 and second housing 320 may now be joined to create a secure water resistant swivelable connection between cable segments 42 and 44. V-ring 400 is placed over male housing outer surface 319 and adjacent to first housing radial collar 336 and O-ring 390 is placed on first housing extension 331. This may also be done before stereo jack 370 is inserted into first housing 330. First housing 330 may be inserted into the second housing insertion bore 323 until O-ring 390 contacts second housing annular collar 324 and the V-ring 400 contacts the second housing annular end wall 321. Further axial pressure may be exerted to force locking sleeve protuberances 345 over first housing radial collar step 337. Locking sleeve 340 is dimensioned such that when protuberances 345 have engaged step 337 an axial pressure is exerted urging first housing 330 toward second housing 320 and compressing O-ring 390 and V-ring 400 so that each creates a water resistant seal.
The assembled cable connector 310 is shown in
The cable connector 310 may be conveniently constructed from a wide variety of materials readily apparent to those skilled in the art. It is particularly convenient if all the components other than the stereo jack and stereo receptacle are constructed from materials which are particularly poor conductors of electricity such as typical polymers used in engineering construction. It is also convenient if the weight of the cable connector is minimized and the engineering polymers such as the polyacetals are helpful in this regard. From a fabrication point of view, it is convenient if the cable connector is fabricated of injection moldable materials. It is convenient if certain of the components are constructed of materials with properties particularly suited to their functions. For instance, it is helpful if the O-rings and V-ring are fabricated from elastomeric materials with appropriate Shore hardnesses for sealants and the fingers are constructed of materials able to undergo elastic deformation sufficient to undergo the deformations encountered in assembling the cable connector 310. It is convenient if the locking sleeve 340 is constructed of a material that not only undergoes elastic deformation but also exerts a sufficient return force to assure sealing of the annular collars O-Ring 390 and the V-ring 400 when the locking collar 340 is in a locked position, i.e. the cable connector 310 is fully assembled. It is also convenient if the cable grasping sleeves 450 and 460 are constructed of an elastomeric material with sufficient compressibility to conform to the outer surface of typical power cables for robotic pool cleaners and the sloping surfaces 354 of and end cap 350. It is also helpful if they have a high coefficient of friction. Rubber and rubber like polymers such as nitrile rubbers with a 50 to 55 durometer have a suitable combination of these properties.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention. A number of features are disclosed herein. These features may combined in multiple combinations such that features may be used alone or in any combination with any of the other features.
This patent application claims priority to International Application No. PCT/US2014/024277, filed Mar. 12, 2014 which is a continuation-in-part application of U.S. application Ser. No. 13/965,597, filed Aug. 13, 2013, which claims priority to U.S. Provisional Application No. 61/788,162, filed Mar. 15, 2013, the content of which are incorporated herein by reference in their entireties.
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PCT/US2014/024277 | 3/12/2014 | WO | 00 |
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WO2014/150807 | 9/25/2014 | WO | A |
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Number | Date | Country | |
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Number | Date | Country | |
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61788162 | Mar 2013 | US |
Number | Date | Country | |
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Parent | 13965597 | Aug 2013 | US |
Child | 14776824 | US |