Releasable electrical connector

Abstract

A connector for connecting an electrical cable to an aperture in an electrical panel having a spring, a shell, and a insulator along a longitudinal axis. The spring has a base from which two insertion tabs extend coaxial with the axis and a pressure tab extending from the base perpendicular to the two insertion tables having a pressure prong to provide a radial grounding force for the connector. The insertion tabs of the spring have hook latches extending past the insulator that lock the connector in the panel and the base of the spring has a hole to receive the cable where first and second clamping tabs clampingly lock the cable in the connector.

Claims

1. A connector for connecting an electrical cable to an aperture in an electrical panel, comprising: a one piece spring, a shell, and an insulator collectively having a longitudinal central axis extending there through when the connector is assembled; said spring having a base from which two side insertion tabs bend around the said axis and a pressure tab extending from the base perpendicular to the two side insertion tabs, and said insulator having a joining wall and a springing feature, and said shell having a through opening coaxial with said longitudinal central axis, wherein said insertion tabs springingly retain said spring in said through opening of said shell, and wherein said springing feature retains said insulator in said through opening of said shell; said insertion tabs of said one piece spring having hook latches extending past said shell to snappingly lock the connector in the panel when axially pressed into the aperture; said pressure tab having a pressure prong to provide a radial grounding force for the connector; and said base of said spring further having a hole to receive the cable when axially pressed into the connector, and a first clamping tab and a second clamping tab, and a third clamping tab to clampingly lock the cable in the connector.

2. The connector of claim 1, wherein said spring is made of sheet metal.

3. The connector of claim 1, wherein the panel has wall material proximal to the aperture and said hook latches of said insertion tabs of said spring each have at least one perpendicularly extending barb to grip into the wall material of the panel.

4. The connector of claim 1, wherein the cable has a spiral or helix shaped side and said first clamping tab and said second clamping tab are differently sized to clamp against the spiral or helix shaped side of the cable.

5. The connector of claim 1, wherein the panel has wall material proximal to the aperture and wherein said shell has a stopper to abut the connector against the wall material of the panel.

6. The connector of claim 5, wherein the aperture has a circumference and said insulator is a bridge ring corresponding with the circumference.

7. The connector of claim 1, wherein said springing feature of said insulator is a plurality of legs that snappingly engage with said shell.

8. The connector of claim 1, wherein said insulator has a plurality of legs that aligningly engage with said shell.

9. The connector of claim 1, wherein the first clamping tab, second clamping tab and third clamping tab are not axially aligned within the spring.

10. The connector of claim 1, wherein the cable has a spiral or helix shaped side and said at least one clamping tab includes a first prong and a second prong that are differently directed to clamp against the spiral or helix shaped side of the cable.

11. The connector of claim 1, wherein said springing feature of said insulator is a plurality of legs that snappingly engage with said shell.

12. A connector for connecting an electrical cable to an aperture in an electrical panel, comprising: a one piece spring, a shell, and an insulator collectively having a longitudinal central axis extending there through when the connector is assembled; said spring having a base from which two side insertion tabs bend around the longitudinal central axis and a locking tab extending away from each of the side insertion tabs for locking engagement of the spring to the shell; said insulator having a joining wall and a springing feature, and said shell having a through opening coaxial with said longitudinal central axis, wherein said insertion tabs springingly retain said spring in said through opening of said shell, and wherein said springing feature retains said insulator in said through opening of said shell; said insertion tabs of said one piece spring having hook latches extending past said shell to snappingly lock the connector in the panel when axially pressed into the aperture; and said base of said spring further having a hole to receive the cable when axially pressed into the connector, and a first clamping tab, a second clamping tab and a third clamping tab to clampingly lock the cable in the connector; and wherein the spring includes a pressure tab extending from the base perpendicular to the two side insertion tabs, wherein the pressure tab has a pressure prong to provide a radial grounding force for the connector.

13. The connector of claim 12, wherein said spring is made of sheet metal.

14. The connector of claim 12, wherein the panel has wall material proximal to the aperture and said hook latches of said insertion tabs of said spring each have at least one perpendicularly extending barb to grip into the wall material of the panel.

15. The connector of claim 12, wherein the cable has a spiral or helix shaped side and said first clamping tab and said second clamping tab are differently sized to clamp against the spiral or helix shaped side of the cable.

16. The connector of claim 12, wherein the panel has wall material proximal to the aperture and wherein said shell has a stopper to abut the connector against the wall material of the panel.

17. The connector of claim 16, wherein the aperture has a circumference and said insulator is a bridge ring corresponding with the circumference.

18. The connector of claim 12, wherein the first clamping tab, second clamping tab and the third clamping tab are not axially aligned within the spring.

19. The connector of claim 12, wherein the cable has a spiral or helix shaped side and said at least one clamping tab includes a first prong and a second prong that are differently directed to clamp against the spiral or helix shaped side of the cable.

Description

BRIEF DESCRIPTION OF THE DRAWING(S)

(1) The purposes and advantages of the present invention will be apparent from the following detailed description in conjunction with the appended figures of drawings in which:

(2) FIG. 1 is an isometric view of an exemplary embodiment of an electrical connector according to the present invention that is aligned with a junction box or panel at a knock out hole or aperture and also aligned with an electrical cable prior to connection.

(3) FIG. 2 is an isometric view of the electrical connector, junction box or panel, and cable of FIG. 1, wherein FIG. 2 shows these elements after connection.

(4) FIG. 3 is an exploded isometric view of the connector of FIG. 1.

(5) FIG. 4 is exploded side view, shown on top and exploded top view, shown on bottom of the connector of FIG. 3.

(6) FIG. 5 is back and top view of the spring on the left side and back and top view of the shell on the right side of the figure.

DETAILED DESCRIPTION OF THE INVENTION

(7) An embodiment of the present invention is an electrical connector with release and fit buttons. As illustrated in the various drawings herein, and particularly in the views of FIGS. 1 and 2, wherein the embodiment of the invention is depicted by the general reference character 10. FIGS. 1, and 2 depict one exemplary embodiment of an electrical connector 10 according to the present invention. FIG. 1 is an isometric view of the connector 10 aligned with a knock out hole or aperture 2 in an electrical panel 1 and with an electrical cable 3 prior to connection. FIG. 2 is an isometric view of the connector 10 after connection. As can be seen in these figures, the connector 10 secures into the aperture 2 of the panel 1 and securely receives the cable 3. In practice, the cable 3 will support a plurality of electrical wires (not shown), which may be already present in the cable 3 or installed through the cable 3 later.

(8) The transition from the pre-connection state in FIG. 1 to the post-connection state in FIG. 2 involves two operations. The cable 3 is pressed into locking engagement with the connector 10, and then the connector 10 is snapped into locking engagement in the aperture 2 of the panel 1. Alternately, the order of these operations can be reversed, snapping the connector 10 into the aperture 2 and then pressing the cable 3 into the connector 10. How the connector 10 facilitates these snap and press together operations is discussed in detail, presently. It is helpful, however, to appreciate now and throughout this discussion that these operations are manual, here meaning that they can be performed entirely by hand and without any tools. The snap and press insertions here are also essentially linear operations, that is, not requiring any rotational screwing or locking together of pieces to employ the connector 10.

(9) FIG. 3 is an exploded isometric view of the connector 10. As shown, the connector 10 here consists of three major components: a spring 12, a shell 14, and an insulator 16. Collectively these components have a longitudinal axis 15, as shown.

(10) The spring 12 is preferably made of die-stamped and formed metal (e.g., from galvanized steel sheet), the shell 14 is preferably made of cast metal (e.g., aluminum, zinc, or pots metal), and the insulator 16 is preferably made of molded plastic (e.g., polycarbonate), although neither these particular materials or these manners of forming them are requirements. FIG. 3 further shows the detailed features of each component.

(11) The first major component of the connector 10 is the spring 12. It is resilient and electrically conducting, and it has a base plate 58 that extends to form pressure tab 51 as the base support of the pressure prong 50, and two insertion tabs 46 angled on the sides perpendicular to the base plate 58. Two more tabs further are bent from the far most ends of the insertion tabs around longitudinal central axis joining in the middle and parallel with the base plate forming the gripping tabs 47. The two insertion tabs are perpendicular from the base plate and the two gripping tabs are parallel with the base plate. The four tabs form a square or rectangular profile conforming the shell housing. The two side insertion tabs 46 each has one or more prongs bent inward with jugged-in sections and free end tips to form gripping prongs 42. The base plate 58 also has a similar prong with a free end tip 48 bent at an angle towards the central axis 15-17. The clamping tabs can have a plurality of barbs 44 bent towards the axis with free end tips to better support gripping the cable. The insertion tabs 46 are bent to form spring buttons 54. The spring buttons would pop out of the shell side openings 32 to press and release the spring 12 inside and out of the aperture hole 2. The insertion tabs have free end tips 41 and each tip has two side extensions barbs 40 bent at an angle to form hook latches. The resilient insertion tabs push the hook latches against the inner wall of the panel 1. When the connector is pushed through the panel aperture 2, the hook latches slide over the edge of opening against spring force of the insertion tabs 46. When they pass the over the edge of aperture 2, the spring force pushes and the latches snap into the aperture such that the side sections abut the panel around the aperture 2. And the hook latches are directed away from the axis to directingly extend into the aperture and snappingly lock the connector 10 in the aperture 2. The spring base plate 58 has a pressure tab 51 extended toward the leading end along the central axis with free end tip. The pressure tab has a pressure prong 50 on the tab that is bent away from the axis with the free end tip either toward the trailing end (shown in this embodiment) or alternatively bent with the free end tip toward the leading end. The spring 12 has two combined spring actions, wherein the insertion tabs 46 perform latching to the aperture 2 and the pressure tab 51 provides necessary pressure via prong 50 to securely ground the connector 10. All insertion tabs 46 and pressure tab 51 together provide gripping cable 3 with the support of gripping tabs 47 while securing grounding continuation through cable 3.

(12) The base plate 58 and the extended side insertion tabs 46 nominally conform to the inner rectangular shape of the shell 14 to permit insertion of a cable 3. The base plate 58 is at a defined trailing end of the connector 10, thus also defining an opposite leading end of the connector 10 (on the insulator 16, left most in FIG. 3).

(13) The two insertion tabs 46 can be the same in general shape. Each extends, as shown, from opposite sides of the base plate 58 at an angle of 90 degrees or less. The insertion tabs 46 have a extruded section that forms a fit/release button, described presently. The insertion tabs 46 are further each extended to form respective hook latch bases. The hook latch bases have two angled barbs 40 on the side of the tab end tip, as shown. As also shown, the barbs 40 can optionally have a triangular or curved cutout between adjacent pairs to permit better grip on the inner wall of a panel 1. The corners of the barbs can also operate to penetrate through a paint or oxidation layer on the inner wall, to reach an underling metal wall material of the panel 1 and thus provide better electrical conductivity and grounding.

(14) Two locking tabs 56 bend outward from the two insertion tabs 46 to secure the spring inside the shell from pulling out. Each insertion tab 46 provides a base from which one or more prongs extend at an angle less than 90 degree to form the side gripping prongs 42. The two gripping prongs 42 can also have the same shape, but preferably there are minor differences to facilitate better engagement with the spiral or helix shaped sides of a cable 3. An inward bent prongs from base plate 58 forms the gripping prong located on top 48. In FIG. 3 one of the insertion tabs 46 is clearly presented, whereas the other one is almost entirely hidden behind other structure along with the gripping tabs 47. The respective prongs in each of these sets can also be the same in size and degree of inward bend, but preferably are slightly different, again to facilitate better engagement with the spiral or helix shaped sides of a cable 3, and thus better securing the cable 3 inside the connector 10, providing better electrical conductivity and grounding.

(15) The second major component of the connector 10 is the shell 14. It is rigid, typically also electrically conducting, and, as shown, it has a nominally square or rectangular cross section. The shell 14 has a base 27, two support columns 26, one trailing bridge 30, and two trailing side bridges 33 forming the trailing opening 31. Further the base 27 and two columns 26 terminate in to a perpendicular plate 28 forming a base for the leading nose 20, two opening windows 32 through which spring buttons 54 extrude out, and an opening 29 on top shown in FIG. 5 through which the spring pressure tab 51 passes. The leading nose 20 extends out of perpendicular plate 28 towards the leading end shown in FIG. 3 forming a flat base 22 to support spring pressure tab 51, two opening windows 21 through which the spring hook latch base and barbs 40 extends outwards. The leading nose 20 forms a collar that sits against the aperture 2 and it has an forward opening 25 through which the electrical conductors (not shown) of the cable 3 passes. The plate 28 also has a corresponding opening to the opening 25 to allow passage of the conductors through (not shown). The hole 25 further receives the insulator 16. In the back of the plate 28, facing the trailing end, there is a recessed cut 34 on which the insulator 16 snaps securely through a plurality of two or more snapping legs 70, here 4 legs.

(16) The third major component of the connector 10 is the insulator 16. It has two guiding bodies 61 and 62 extending out of ring or base 60 having a circular or oval opening 68. The guiding bodies 61 and 62 match the contour of the shell 14 and slide through hole 25. The insulator 16 is completed by a plurality of snapping legs 70 (four here, two visible in FIG. 3 and four visible in FIG. 4).

(17) To assemble the embodiment of the connector 10 depicted in FIG. 3 the spring ring 12 is inserted in a first operation into the through opening 31 of the shell 14 and then the insulator 16 is inserted in a second operation into the through opening 25 of the shell 14.

(18) The first insertion operation includes inwardly displacing the press sections 54 of the insertion tabs 46 sufficient to permit passage of the insertion tabs 46 between the side bridges 33 of the shell 14. At the same time, the pressure tab 51 slides underneath trailing bridge 30 and sits over flat area 22 of shell 14. A final press slides the spring 12 tightly inside shell 14. Once the spring 12 is brought to its final position in the shell 14, the two locking tabs 56 snap out of openings 32 on shell 14 fitting spring 12 firmly inside shell 14 securing strong electrical conductivity and grounding between spring 12 and shell 14. Once the spring 12 is brought to its final position in the shell 14, the two spring buttons 54 pop out of two openings 32 and the insertion tab spring back displacement constrains base 41 on each insertion tab 46 against columns 35 of plate 28, thus trapping the spring 12 in the shell 14. In this manner the spring buttons 54 are used as fit buttons during assembly (and can be used as release buttons for disassembly).

(19) The second insertion operation includes snapping the insulator 16 into the sub-assembly of the shell 14 and spring 12. The insulator 16 is passed into the through opening 25, sliding two guiding bodies 61 and 62 inside opening 25 with the snapping legs 70 of the insulator 16 against the recessed area 34 of the shell 14, thus locking the insulator 16 within the sub-assembly of the shell 14 and spring 12.

(20) To connect the connector 10 to a panel 1, the spring buttons 54 of the insertion tabs 46 are pressed, thus inwardly moving the hook latches barbs 40 enough to pass the leading end of the connector 10 into an aperture 2. When then released, the insertion tabs 46 bounce back, outward, to grip into the inner wall of the panel 1 through barbs 40.

(21) To connect a cable 3 to the connector 10, the cable 3 is pushed through the hole 31 at the trailing end of the connector 10, until the cable 3 abuts against the insulator 16, where it is then locked into place by the grip of the prongs (e.g., by the prongs 44 of clamping tab 47, the prongs 44 of base plate 58, and prongs 42 of insertion tabs 46).

(22) To disconnect the connector 10 from the panel 1, the spring buttons 54 of the insertion tabs 46 are again pressed, thus inwardly moving and disengaging the hook latches, disengaging barbs 40 enough to remove the leading end of the connector 10 from the aperture 2.

(23) To disconnect the connector 10 from the cable 3, the connector 10 can be rotated counter-clockwise to unscrew the connector 10 from the cable 3 (since the prongs 44 of clamping tab 47, the prongs 44 of base plate 58, and prongs 42 of insertion tabs 46 are in screw-thread-like engagement with the spiral groove of the cable 3).

(24) In summary, it can now be appreciated that the connecting and disconnecting of cables 3 to panels 1 with the connectors 10 can be entirely manual, requiring little effort and no tools. The linear connecting operations of squeezing and inserting a connector into knock out hole or aperture and pressing a cable into the connector permitted by the present connector 10 should especially permit time savings during electrical construction. Similarly, to the extent rarely ever needed, the linear disconnecting operation of squeezing and withdrawing the present connector 10 from a knock out hole or aperture and the rotational disconnecting operation of unscrewing the present connector 10 from a cable will also permit time savings over the use of other types of connectors.

(25) The present invention offers a quick connect connector for an electrical junction box or panel that requires no tools for connection or removal of the connector. Moreover, it needs much less effort and force for installation or removal compared to the existing snapping connectors. Due to its unique design, there are large contact areas between the electrical junction box or panel, the connector, and the jacket of the electrical cable that in turn results in a very good electrical continuity and grounding.

(26) While various embodiments have been described above, it should be understood that they have been presented by way of example only, and that the breadth and scope of the invention should not be limited by any of the above described exemplary embodiments, but should instead be defined only in accordance with the following claims and their equivalents.