Patent Publication Number: US-6981890-B2

Title: Electrical connector with improved locking means

Description:
RELATED APPLICATION 
     The present application is a continuation of U.S. application Ser. No. 09/340,234, filed Jul. 1, 1999 now U.S. Pat. No. 6,257,919. 
    
    
     FIELD OF THE INVENTION 
     This invention relates to an electrical connector having a multiple spring locking mechanism. 
     BACKGROUND OF THE INVENTION 
     The standard wire nut is a common device currently available for electrically and mechanically interconnecting two or more segments of electrical wiring. First, the individual sections of wire are twisted together and then the nut is screwed onto the wire. This procedure is usually tedious and time consuming, particularly for residential and business construction applications wherein a large number of connections are typically needed. Effectively securing the nut to the wires usually requires practiced skill and experience. As a result, labor costs tend to be high. Conventional wire nut connections also tend to be less than optimally secure. Wires are apt to loosen and become disconnected. Considerable time and effort may be required to locate and repair a defective connection. 
     Crimp connectors are also widely used. However, the crimping process often destroys the connector and renders it ineffective. It is usually quite difficult to perform the crimping process correctly. Moreover, the crimp connector tends to pull apart from the wire fairly easily. 
     Soldering electrical conductors together necessitates the use of soldering equipment, supplies and a power source. The soldering process again usually requires a measure of skill and experience. This type of electrical connection is often difficult to perform in the field. 
     Wire trap connectors have also been used to join segments of electrical wiring. These devices typically employ a spring clip contact mounted within a multiple piece plastic housing. Electrical wires are introduced through openings in the housing to engage the contact. The wires are held in place by respective spring clips. This device represents an improvement over previous connectors; however, it is still often possible for the wiring to separate from the connector. Moreover, in some cases, if the wiring is pulled with sufficient force, the individual parts of the housing can separate to expose the electrical contact and the ends of the wiring. This can result in failure of the wiring. Additionally, known wire trap connectors are ineffective for use with stranded wire, which lacks the rigidity needed to open the spring clip. 
     A need exists for a connector that is not only quick and convenient for both skilled and unskilled persons to use but also provides an improved and much more secure mechanical and electrical connection. A need also exists for a connector that can be employed in a wide variety of applications and environments. 
     SUMMARY OF THE INVENTION 
     It is therefore an object of this invention to provide an electrical connector that provides for a significantly improved locking interconnection between segments of electrical wire or other type of electrical conductor. 
     It is a further object of this invention to provide an electrical connector that mechanically joins respective conductive components so securely that it is virtually impossible to unintentionally disconnect the components. 
     It is a further object of this invention to provide an electrical connector that permits large numbers of electrical connections to be made quickly and conveniently, even by persons with little or no electrical training, and which is therefore extremely desirable for use in many various residential, commercial, industrial, marine and other applications. 
     It is a further object of this invention to provide an electrical connector that employs a virtually indestructible one piece enclosure which resists being pulled apart even under enormous stress. 
     It is a further object of this invention to provide a virtually indestructible assembly which resists being pulled apart even under enormous stress. 
     It is a further object of this invention to provide an electrical connector that locks sections of electrical wire securely together but which employs a convenient, optional spring release mechanism that allows the wires to be disconnected (and stranded wire to be connected), as required. 
     It is a further object of this invention to provide an electrical connector that improves both mechanical and electrical connection by using a spring lock that grips the conductive components at multiple locations. 
     It is a further object of this invention to provide an electrical connector that achieves considerable time, labor and expense savings in commercial, residential, industrial, marine and other applications. 
     It is a further object of this invention to provide an electrical connector that exhibits a substantial area of electrical contact and which achieves improved electrical conductivity while generating minimal heat. 
     It is a further object of this invention to provide an electrical connector that works effectively with virtually all types of wires and other electrical conductors, including stranded, solid and shielded wire. 
     It is a further object of this invention to provide an electrical connector that is extremely convenient to use and install in the field. 
     It is a further object of this invention to provide an electrical connector that exhibits improved durability and is virtually indestructible. 
     It is a further object of this invention to provide an electrical connector that may be used in a wide variety of electrical applications and connecting environments including, but not limited to wiring, plugs, fixtures, appliances, switches, receptacles and service panels. 
     This invention features a looking connector for electrically interconnecting first and second electrical conductors, such as first and second sections of electrical wire. An electrical contact component is electrically interengaged with the first conductor. The contact component includes first and second, spaced apart contact sections and an intermediate contact section that interconnects the first and second sections. The intermediate contact section includes an opening that receives the second conductor. A set of at least two spring locking clips are mounted to the first contact section and generally serially arranged to face away from the opening in the intermediate contact section such that the clips are sequentially and resiliently opened by introducing the second conductor through the opening. The clips are spring biased to grip the second conductor at a plurality of locations and hold the second conductor in electrical interengagement with the second contact section. As a result, the clips resist disengagement of the second conductor from the contact component. 
     In preferred embodiments, the device further includes an enclosure that accommodates the contact component and the spring clips. The enclosure has an inlet aligned with the opening for receiving the second conductor. 
     The contact component may include a unitary, conductive element. The first and second contact sections may comprise a generally parallel pair of plates. The spring clips may be secured to a first plate and spring biased to urge the conductor against the other, second plate. At least one of the spring clips may comprise a leaf spring. Each spring clip may include a first generally planar segment that engages and is connected to the first plate, a second segment that is connected to the first segment at an angle and unitary spring means for urging the second segment apart from the first segment and into gripping interengagement with the second conductor. 
     The first plate may carry a pair of generally parallel lips that extend transversely therefrom. The first segment of one of the clips may be interconnected between the intermediate contact section wall and one of the lips, and the first segment of the other clip may be interconnected between the pair of lips. A distal lip may extend transversely from the second plate for limiting the extent to which the second conductor may be introduced through the opening of the contact. The second plate may include guide means for locating the second conductor relative to the second plate. This guide means may comprise an elongate rib formed in the second plate. 
     Release hole means may be formed through the enclosure and the second plate for receiving a release element. The release element may include a plurality of pins that are inserted through respective release holes formed through the enclosure and the second plate of the contact. The release element thereby urges the second spring clip segments simultaneously into an open condition wherein the second segments are disengaged from the second conductor such that the second conductor may be removed from the enclosure. 
     In various embodiments, multiple wires or other conductors may be secured by respective serially arranged pairs of spring clips constructed in the above manner. Three or more aligned spring clips may also be used for locking a respective conductor in interengagement with the contact. 
     The locking connector may be employed in a wide variety of household and commercial applications. For example, the connector may be utilized to releasably interconnect two or more sections of electrical wiring. Alternatively, the connector may be employed in a plug, electrical service panel, lighting fixture, light switch box and various industrial, marine and other applications. Serial and parallel connections may be made. 
     These and other objects, advantages, features and aspects of the present invention will become apparent as the following description proceeds. 
     To the accomplishment of the foregoing and related ends, the invention, then, comprises the features hereinafter fully described and particularly pointed out in the claims, the following description and the annexed drawings setting forth in detail certain illustrative embodiments of the invention, these being indicative, however, of but several of the various ways in which the principles of the invention may be employed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the annexed drawings: 
         FIG. 1  is an enlarged perspective view of a preferred locking connector assembly according to this invention; 
         FIG. 2  is a perspective view of a preferred electrical connector in which the locking connector assembly of  FIG. 1  is incorporated in an enclosure; 
         FIG. 3  is an enlarged fragmentary longitudinal section through the electrical connector of  FIG. 2 ; 
         FIG. 4  is a front elevational view of the enclosure of  FIG. 2 ; 
         FIG. 5  is a top plan view of the enclosure; 
         FIG. 6  is a rear elevational view of the enclosure; 
         FIG. 7  is a side elevational view of the right hand side of the enclosure, the other side being a mirror image; 
         FIG. 8  is a bottom plan view of the enclosure; 
         FIG. 9  is a top plan view of the electrical contact component of the locking connector assembly prior to assembly; 
         FIG. 10  is a front elevational view of the front end of the electrical contact component of  FIG. 9  after assembly; 
         FIG. 11  is a top plan view of the electrical contact component of  FIG. 10 ; 
         FIG. 12  is an elevational view of the rearward end of the electrical contact component of  FIG. 10 ; 
         FIG. 13  is a bottom plan view of the electrical contact component of  FIG. 10 ; 
         FIG. 14  is a top plan view of a preferred spring locking clip of the locking connector assembly in a pre-assembled condition; 
         FIG. 15  is an elevational side view of the electrical contact component and spring locking clip in a fully folded and assembled condition; 
         FIG. 16  is a front elevational view of a preferred spring release tool; 
         FIG. 17  is an elevational side view of the spring release tool of  FIG. 16 ; 
         FIG. 18  is a top plan view of an alternative spring locking clip according to this invention in a pre-assembled condition; 
         FIG. 19  is an enlarged fragmentary longitudinal section through an alternative electrical connector according to this invention for making end to end wire connections; and 
         FIG. 20  is an enlarged fragmentary longitudinal section through an electrical plug that incorporates the connector of this invention. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     There is shown in  FIG. 1  a preferred form of locking connector assembly  2  in accordance with this invention. The assembly features a conductive contact component  4  that carries a pair of serially arranged spring locking clip components  6  and  8 . Assembly  2  may be used to accomplish a virtually limitless variety of electrical connections. The assembly may be carried within a plastic enclosure as described below, may be used without an enclosure and/or may be incorporated into various appliances, fixtures, switches, plugs and other items that require electrical connection. 
     There is shown in  FIG. 2  a preferred electrical connector  10 , which includes the locking connector assembly  2  mounted in a rectilinear enclosure  12  according to this invention. Connector  10  is designed for electrically and mechanically interconnecting a plurality of wires or other types of electrical conductors in a quick, secure and reliable manner. In the version shown in  FIG. 2 , five electrical wires  14 ,  16 ,  18 ,  20  and  22  are joined by connector  10 . In alternative versions of this invention, various other numbers of wires may be interconnected by the device. These wires may be attached to the same end of the electrical connector, as shown in  FIG. 1  or alternatively, may be joined to opposing ends of the connector, in a manner that is more fully described below. The connector of this invention may also be incorporated into a device or appliance such as an electrical service panel, plug, electrical fixture or switch that is engaged by a wire or other conductor. It should be understood that connector  10  may be employed for virtually all household, commercial, industrial, marine and other applications wherein electrical connection is required. 
     Enclosure  12  is shown alone in  FIGS. 4 through 8  and preferably features a molded or fused unitary plastic construction including front and rear ends  24  and  26 , respectively, top and bottom  28  and  30 , respectively and left-hand and right-hand sides  32  and  34 , respectively. In certain versions, the enclosure  12  may comprise two separate pieces that are fused together such as along seam  36  in  FIG. 3 . Alternatively, the enclosure may comprise a unitary molded plastic. A peripheral ridge  38  may be formed unitarily in the enclosure such that it surrounds the enclosure. Additionally, each end of the enclosure may include one or more recesses. For example, ends  24  and  26  include recesses  40  and  42 , respectively. Top  28  and bottom  30  each feature a pair of respective recesses  44 ,  46 , and  48 ,  50 ; and sides  32  and  34  include a pair of recesses  52  and  54  (shown only for side  34  in  FIG. 7 ). The peripheral ridge  38  and the recesses  40  through  54  provide the enclosure  22 , and therefore connector  10 , with a much improved grip so that electrical wires may be more conveniently connected to and, if necessary, removed from the connector. 
     Various types of holes, apertures or openings may be formed in enclosure  12 . As shown in  FIGS. 2 ,  3  and  4 , a plurality of inlets  60 ,  62 ,  64 ,  66  and  68  are formed side by side in front end  24 . Each inlet is sufficiently large to accommodate a respective one of the wires  14  through  22 . For example, wire  14  is shown positioned for insertion into inlet  60  in  FIG. 2 . The remaining wires are respectively positioned for insertion into the other inlets in a similar manner. Enclosure  12  also includes various other optional openings such as an electrical conductivity test hole  70  that is formed in rear end  26 , as shown in  FIG. 6 . Also a pair of spring release holes  72 ,  FIG. 8 , may be formed in recesses  48  and  50  of bottom surface  30 . Holes  70  and  72  function as described more fully below. 
     As best illustrated in  FIG. 3 , the locking connector assembly  2  is permanently mounted within enclosure  12 . Assembly  2 , shown by itself in  FIG. 1 , includes a contact component  4  having a generally C-shaped cross sectional configuration, and a pair of leaf spring locking clips  6  and  8  mounted within contact component  4 . 
     Contact component  4  is depicted by itself in  FIGS. 9 through 13 . Initially, as best shown in  FIG. 9 , the contact component  4  is constructed from a substantially flat sheet composed of a conductive metal material. This may include tin plated copper or other conductive materials that will be known to those skilled in the art. The contact sheet is cut, stamped and/or otherwise machined to include an assortment of features. For example, a plurality of transverse fold lines  90 ,  92 ,  94  and  96  are formed in the contact strip. Fold line  90  separates a first lip section  98  from a first plate section  100 . Fold line  92  divides plate section  100  from an intermediate wall section  102 . Third fold line  94  separates wall section  102  from a second plate section  104 . Finally, fold line  96  separates plate section  104  from a lip section  106 . Transverse cuts  108  and  110  are formed in opposite edges of plate  100  and the cut material is folded downwardly (i.e., in a direction into the drawing) to form additional lips  112  and  114  that depend from plate  100 . 
     A plurality of openings or apertures  116  through  124  are formed side by side in wall section  102 . These apertures correspond in number and location, and are aligned with the inlet holes  60  through  68  formed in enclosure  12 . It should be understood that in alternative embodiments, various other numbers of apertures may be formed in wall section  102 . In still other versions, the intermediate wall  102  and second plate  104  may be eliminated and spaced apart contact sections, or at the least a single contact section, may be mounted within an enclosure. A plurality of substantially parallel guide ribs  126 ,  128 ,  130  and  132  are formed longitudinally front to back in contact section  104 . These ribs define a plurality of aligned channels  136  that accommodate respective electrical wires when the contact component  4  is assembled in the manner described below. A pair of spring release holes  140  are formed through rib  126 . In alternative versions additional release holes may be formed in one or more of the other ribs. Each rib is formed such that it is aligned with the space between an adjoining pair of the apertures  116  through  124  in wall  102 . 
     A contact component  4  constructed preliminarily in the manner shown in  FIG. 9  is fully assembled as shown in  FIGS. 10 through 13 . Specifically, the contact  4  is folded along fold lines  90 ,  92 ,  94  and  96 . As a result, contact  4  assumes the shape shown in  FIGS. 1 ,  3 ,  10  through  13  and  15 . Plates  100  and  104  are spaced apart and interconnected by wall  102 . The plates maintain a generally parallel condition relative to one another. Lip  98  depends from upper plate  100  as shown in  FIGS. 1 ,  3 ,  11 ,  12  and  15 . Likewise, lips  112  and  114  depend from plate  100 . Distal lip  106  extends upwardly from plate  104 ,  FIGS. 1 ,  3 ,  12 ,  13  and  15 . Ribs  126  through  132  extend along the inside, upwardly facing surface of plate  104 . The apertures  116  through  124  are arranged side by side across wall  102  and each aperture is aligned with a respective channel  136 , as best shown in  FIGS. 1 and 9 . 
     Leaf spring locking clips  6  and  8 ,  FIGS. 1 ,  3  and  15 , are attached to contact component  4 . A preferred spring clip  6  is shown prior to assembly in  FIG. 14 . It should be understood that spring clip  8  and any other spring clips used in the connector are preferably constructed in an analogous fashion. Typically, the spring clip is formed from a generally flat piece of resilient metal. Non-metallic springs may also be used. A fold line  150  is formed transversely across the clip. This material should have sufficient resilience such that it serves as a leaf spring when the component is folded or bent along fold line  150 . More particularly, clip  6  includes a first planar segment  152  and a second planar segment  154  that is cut longitudinally at spaced apart intervals to form spring arms  156 ,  158 ,  160  and  162 . Spring arm  156  has a width that is approximately twice as great as the remaining spring arms. The spring arms are shown with transversely flat configurations; however, some embodiments of the spring arms may be transversely curved (see phantom edge  159  in  FIG. 14 ) to conform to the shape of a wire to be contacted. The clip is folded along fold line  150  and inserted into contact  4  (either before or after the contact is assembled) such that clip segment  152  extends between wall  102  and lip  112 . See  FIGS. 1 ,  3  and  15 . This fit is sufficiently tight such that the spring clip is held permanently in place in the contact  4  and effectively becomes part of the contact. It should be noted that the opposite end of segment  152  similarly fits between wall  102  and opposite depending lip  114 . The folded segment  154  of component  6  depends downwardly from segment  152  at an angle and the folded leaf spring includes a spring bias that urges segment  154  downwardly as indicated by arrow  160  in  FIG. 3  into the phantom line position shown in  FIG. 3 . 
     The second spring clip  8  is constructed in a similar manner and is likewise mounted permanently within contact component  4 . In this case, the upper clip segment  152  is fit securely between lips  112  and  114 , and lip  98 . The locking spring clip is folded and again includes a spring bias that urges clip segment  154  downwardly as indicated by downward arrow  160  in  FIG. 3 . Alternative means may be employed for securing the spring clips to the contact component. 
     The spring clip components  6  and  8  are mounted in the above described manner within contact  4  and are arranged serially with a pair of serially arranged spring arms  156  generally aligned with and facing angularly away from one or more of the apertures  116  through  124 . When the spring clip shown in  FIG. 14  is used, wide spring arm  156  is aligned with two apertures  116  and  118 . Alternatively, each spring arm may be aligned with a single respective aperture. 
     The version shown herein depicts two serially arranged spring contacts. However, in alternative versions three or even more spring contacts may be assembled within a contact component in an analogous fashion. As used herein, “serially arranged” means that the depending segments (spring arms) of each set of spring clips are oriented relative to one another and relative to an associated enclosure inlet and associated contact aperture such that, as described below, insertion of a wire into the connector causes the depending spring biased segments of the clips to be sequentially opened. In other words, each of the corresponding depending segments faces angularly away from and is in general alignment with an inlet in the enclosure and an associated aperture in the base portion of the contact. 
     In the embodiment shown in  FIG. 1 , a locking connector assembly  2  manufactured in the foregoing manner is permanently installed within enclosure  12 , as best shown in  FIG. 3 . Wall  102  abuts a shoulder  170  and a rib  172  formed within the inner chamber of enclosure. Likewise, the distal lips  98  and  106  abut the inside of enclosure wall  26 . 
     Wires  14  through  22  are secured to connector  10  in the following manner. As shown in  FIG. 3 , a respective wire (i.e., wire  14 ) is inserted through its corresponding inlet  60  as well as the aligned aperture  116  in contact component  4 . The insulating jacket  180  of the wire is first stripped to a predetermined length and the exposed conductive wire element  182  is inserted through contact aperture  116  and into the aligned channel  136  defined by rib  126 . The required length of electrical wire to be stripped of insulation may conveniently be determined by placing a suitably placed line  184  on the exterior of the locking connector assembly or any enclosure in which the locking connector assembly is mounted as schematically shown in  FIGS. 2 and 7 . 
     The exposed wire resiliently and sequentially opens the serially aligned spring arms and is pushed through contact component  4  until the distal end of the wire engages and is stopped by lip  106  extending upwardly from plate  104 . The spring bias of contacts  6  and  8  urges the spring arms (for example spring arm  156 ) to bear against and interengage wire element  182  such that the distal end  186  of the outwardly flexed spring arm, shown in solid lines in  FIG. 3 , grips the wire and establishes electrical interconnection between the contact component  4  and wire element  182 . The wire element is held securely between the spring clips and plate section  104 . Wire element  182  is effectively gripped at two locations so that it is securely locked within the connector. The angles and spring bias of the spring arms oppose a removal force applied to the wire element and enhance the locking effect of the connector upon the wire element when the wire is pulled against the connector. The mechanical interconnection is such that it is virtually impossible for the wire element to be inadvertently pulled out of the locking connector assembly and disengaged from the contact. Moreover, a reliable electrical interconnection is established. 
     One or more additional wires (e.g., wires  16 – 22 ) may be joined to the connector in a similar fashion so that the respective wires are both mechanically and electrically interconnected in a secure and reliably operable manner. It should be noted that the angularly depending spring arms  156 – 162  and lower plate section  104  may have curved shapes that complement wire elements  182  so that improved contact is achieved. 
     In certain cases, the user may wish to disengage the wires from connector  10  and/or install stranded wire using the connector. This may be accomplished without damage to the wire or the connector, by employing a spring release mechanism or tool  200 , shown in  FIG. 16 and 17 . Tool  200  features a block or handle  202  that carries a pair of pins  204 . To release the spring lock, the tool is manipulated to insert pins  204  through respective holes  72  in enclosure  12  and corresponding holes  140  in contact component  4 . The pins  204  are pushed through the aligned holes to engage spring arms  156 . By continuing to push on tool  200 , the pins urge spring arms  156  upwardly to disengage exposed wire element  182 . This permits the wire to be disengaged from the contact and removed from the enclosure. 
     Tool  200  is then removed and the spring arms are spring biased into their closed condition represented by  156 ′ (see  FIG. 3 ). In this condition, the spring arms extend across the channel that is accommodated by the wire element when the wire element is inserted into the connector. It should be understood that similar release holes may be employed for releasing any of the serially arranged sets of spring arms  158 – 162  in connector  10 . It should also be noted that the aligned spring release holes  72  and  140  are formed through the connector such that when the release mechanism is inserted, it extends upwardly to engage the spring contact on one side of the inserted wire element. In other words, the wire element does not interfere with insertion of the release mechanism and vice versa. The spring release mechanism is equally effective in opening the spring locking clips to permit the insertion of stranded wire or other conductive components lacking the rigidity or integrity needed to open the spring locking clips by themselves. 
     An alternative spring contact clip  6   a , shown in  FIG. 18 , is designed for use with wires to be permanently connected. In this version, the spring contact clip includes a first segment  152   a  and a second segment  154   a  that includes five spring arms  156   a ,  158   a ,  160   a ,  162   a  and  164   a . Each of the spring arms is aligned with a respective inlet and corresponding aperture. In this version, the spring contact does not include a portion that is engageable by a release tool. Accordingly, it is designed for use in permanent electrical interconnections. Otherwise, the spring clip is manufactured, inserted and used in a manner analogous to that previously described. 
     As shown in  FIG. 3 , electrical connection may also be established between one or more wires, which are joined to the contact component as previously described, and an additional conductor  220 . The distal end of conductor  220  is joined by an H-connector  222  to the lips  98  and  106  of assembly  2 . As a result conductor  220  is designed to permanently interengage the contact  4 . Alternatively, the conductive metal sheet out of which the contact  4  is stamped or otherwise cut may also be stamped or cut to include the conductor  220 ′ as an integral part of the contact as schematically shown in phantom lines in  FIG. 9 . One or more additional wires (e.g., wire  14 ) are then joined to the contact  4  in the manner previously described. As a result, those wires are electrically and mechanically interconnected to conductor  220 . 
     In still other embodiments, multiple pairs of opposing spring clips  6 ′ and  8 ′ may be mounted in opposite ends of a contact  4 ′ and arranged to face in opposite directions in alignment with respective apertures in opposite ends of the lock connector  10 ′ as schematically shown in  FIG. 19 . This construction permits aligned end to end wire connections to be made. Otherwise the details of construction and operation of the connector of  FIG. 19  is substantially the same as the connectors previously described, and the same reference symbols followed by a prime symbol are used to designate like parts. 
     The locking connector of this invention may also be incorporated into various types of electrical appliances and fixtures so that improved connection is achieved. It is not necessarily limited to connecting two or more segments of wire. For example, as shown in  FIG. 20 , an electrical plug  300  carries a case  302  that extends rearwardly therefrom. A locking connector assembly  304  in accordance with this invention is mounted within case  302 . Connector assembly  304  includes a contact component  306  and a pair of serially arranged spring clips  308 . The contact component and spring clips are constructed in a manner identical or similar to that previously described. The distal end of an electrical wire  310  is stripped and inserted into an opening in case  302 . As previously described, contact component  306  includes an opening that is in alignment with the substantially aligned spring clips  308 . When the stripped end of wire  310  is inserted through the contact opening, it resiliently opens clips  308  in a sequential manner. The spring bias of the clips holds them in gripping and electrical interengagement with the wire. The wire electrically interengages contact  306 , which is itself connected to the prongs  314  of plug  300  by an appropriate connector such as the previously described H-connector  316 . Otherwise, mechanism  304  works in a manner similar to that previously described. A plug manufactured in accordance with  FIG. 20  is effective for use in various appliances such as wall lamps. The plug can be permanently connected to the wire, or releasably attached as previously described by using release holes and a corresponding release mechanism. 
     Assorted other types of electrical appliances may employ the locking connector assembly of this invention. For example, the connector may be employed with industry standard connector heads for low voltage and high voltage connections. Likewise, the connector may be employed in high and low voltage plugs and switches. 
     In certain embodiments the previously described enclosure is eliminated or modified to fit a particular application. The contact component and spring locking clips may also employ various alternative configurations in accordance with this invention. The connector accomplishes wire to wire, parallel wire and opposing wire connections. A single connector may join multiple wires. Alternatively, multiple wires may be attached to multiple connectors. A single wire likewise may be joined to a single or multiple connector. The locking mechanism enables various types of switches to be interconnected quickly and conveniently between a pair of wires. Likewise, the locking connector is suitable for attaching wiring to both high and low voltage male and female plugs. 
     The connector of the invention is likewise adaptable for use in light switch boxes and light fixture outlets in residential and commercial applications. Using the locking connector of the present invention is extremely convenient in new construction, remodeling and industrial applications, among others, wherein numerous electrical connections are typically required. The locking design of this mechanism effectively prevents untrained and unskilled persons from disassembling a proper connection and connecting it improperly. Four and five port devices, as described above, are particularly effective for use in new home remodeling and similar industrial and commercial construction use. House wiring is preferably joined to the permanent ports of the connector. The stranded wires from light fixtures are attached to the releasable ports so that light fixtures may be quickly and conveniently installed and removed as required. Various other combinations and configurations of permanent and releasable interconnections may be employed. 
     The present invention eliminates the problems and aggravations commonly associated with crimping, splicing and soldering wires. An opposed, single port version of the locking mechanism effectively replaces crimp style wire connectors. Opposed configurations are particularly useful where alignment of the wires is an important consideration. The locking mechanism may be incorporated into various other devices such as a ring connector for a battery terminal. The device may also be utilized to securely fasten aluminum service cable to the main electrical service panel of the building. The spring clips flex with the normal expansion and contraction of the aluminum cable and therefore maintain a tight and effective connection. 
     The locking mechanism of this invention, in different sizes, may be used effectively with virtually all gauges and types of wires and other electrical connectors. This includes, but is not limited to, house wiring, commercial and industrial building wiring, marine wiring and electronic wiring of the type used in computers and audio equipment. The connector is also effective for use with shielded and coaxial cable. 
     In embodiments featuring an enclosure, the enclosure may be filled with an epoxy, gel or potting compound after the electrical connection is made. Likewise, in embodiments that do not include an enclosure, the connector itself may be filled with an epoxy, gel or potting compound after the connection is made. This protects the connector from moisture and corrosion. 
     The tin plated copper construction and the improved, longer and tighter interengagement between the conductor and the contact achieves significantly improved electrical conductivity and performance. 
     Accordingly, the connector of this invention enables any plurality of electrically conductive components to be mechanically and electrically joined in a quick, convenient and secure manner. Even untrained persons, with little or no electrical knowledge, can perform electrical connections quickly, conveniently and in a virtually failsafe manner. Gripping and electrical interengagement are established at multiple locations along the length of the conductor. As a result, a much improved, secure and highly effective and conductive connection is achieved. Reliable electrical contact is established and unintentional disengagement is avoided. The contact component is substantially longer (front to back) than existing components of this type and the use of a permanently sealed, one piece enclosure prevents the enclosures from being pulled apart under stress or tension. 
     In certain embodiments, the connector can be used in any application that joins two or more wires together and/or joins one or more wires to any other type of electrical connector. 
     While specific features of the invention are shown in some drawings and not in others, this is for convenience only, as each of the features may be combined with any or all of the other features in accordance with the invention. 
     Although the invention has been shown and described with respect to certain preferred embodiments, it is obvious that equivalent alterations and modifications will occur to others skilled in the art upon the reading and understanding of the specification. The present invention includes all such equivalent alterations and modifications and is limited only by the scope of the claims.