BRPI0808793B1 - APPARATUS FOR USE IN FIXING AN ELECTRICAL CONNECTION AND METHOD FOR USE IN FIXING AN ELECTRICAL CONNECTION - Google Patents

Abstract

LOCKING ELECTRICAL SOCKET A method and apparatus (? utility?) for securing an electrical connection formed by a mating structure including pins of a male assembly (50) and sockets of a female assembly (20) are described. The utility includes a clamping mechanism (40) whereby forces that would otherwise tend to separate the connection serve to actuate the clamping mechanism (40), thereby securing the coupled pair. The device can be integrated into a standard socket, or upgraded to work with existing devices. In one embodiment, the clamping mechanism (40) acts only on the ground pin (54) of the standard male assembly (50), so that it is unnecessary to consider the electrical potentials applied to the fixed pin (54) in relation to the model of the clamping mechanism. fixing (40). Additionally, the movement of removing the pin (54) from the male assembly (50) can be converted into rotational movement of a part of the fastening mechanism (40) for a support relationship with the fixed pin (54).

Description

REFERENCE TO RELATED REQUEST

[0001] This application claims priority pursuant to 35 USC §119 to United States Provisional Application 60/894,849, entitled “LOCKING ELECTRICAL RECEPTACLE”, filed March 14, 2007, the contents of which are incorporated herein as shown in full .

FUNDAMENTALS

[0002] A number of electrical connectors are known to provide electrical contact between power sources and electrical devices. Connectors typically include pin-type terminals, generally referred to as plugs, and female connectors, designed to receive pin-type terminals, generally referred to as sockets, often described as electrical outlets, or simply sockets. The most common types of outlets include a pair of terminal contacts that receive the pins of a plug that are mated to “actively current-carrying” and “neutral” conductors. Additionally, receptacles include a terminal contact that receives a ground pin from a plug.

[0003] The plug and socket system model mentioned above generally incorporates a means of fixing only through friction of the two in the conjugate position. The coefficient of friction varies depending on a variety of conditions, including but not limited to manufacturing processes, foreign materials acting as lubricants, and wear and distortion of assemblies. This characteristic results in an unsafe means of interconnecting AC power between two devices. It is questionably the weakest claim on the power supply system for electrical or electronic devices using the system. However, it has been adopted worldwide as a standard, and is mainly used due to the low manufacturing cost, ease of quality control during manufacturing, and efficient use of space for the power supply it is intended to accomplish.

[0004] The main limitation of this connection technique is simply the frictional fitting component. In some applications where power continuity may be crucial, such as in medical applications or data applications, a technique to ensure bond connection may be desirable to improve reliability. This may be especially true in mechanically active locations, such as where vibration is present, or where external activity may cause wires attached to plugs and sockets to be mechanically deflected or stressed in any way.

[0005] In opposition to these antecedents, the electrical locking socket of the present invention was developed.

SUMMARY

[0006] The present invention relates to fixing an electrical connection. In some cases, electrical connections between plugs and sockets may be the least secure connection in the power supply system. Conventionally, these connections are secured only through a friction fit. Some factors may affect the security of this connection. The present invention provides a clamping mechanism whereby forces that would otherwise tend to separate the connection serve to actuate the clamping mechanism, thereby securing the coupled pair. The invention is simple in construction and highly safe in operation. Furthermore, the invention can be implemented simply in connection with new or updated socket devices. Thus, the system is compatible with existing plugs and other infrastructure.

[0007] According to one aspect of the present invention, an apparatus is provided for use in securing an electrical connection. The electrical connection is formed through a mating structure including the pins of a male assembly and the sockets of a female assembly (e.g., a plug socket or cable cover), where the connection is severed by removing the pins to from the sockets. Note that a wall outlet socket is female, while cable covers can be male or female. The apparatus includes a fastening member movable between a fastening configuration, where the fastening element maintains the mating structure in a connected state, and a releasing configuration. An activating element induces the fastening element into the fastening configuration in response to a force tending to withdraw the pins from the sockets. In this way, a force that would otherwise tend to separate the connection will now cause the apparatus of the present invention to secure the connection in a secure state.

[0008] Several structures are possible to implement the highlighted fixing functionality. Such a structure can be associated with the male assembly and/or with the female assembly. In one implementation, the apparatus is implemented only in the female assembly. For example, the fastener may act on one or more of the pins of the male assembly. In a specific implementation, the fastening element acts on a ground pin, maintained at ground potential, in such a way that it is unnecessary to consider the potentials applied to the fixed pin in relation to the fastening element model. This also enables or facilitates compatibility with security code/context rules.

[0009] As noted above, the fastening element may include a contact surface for contacting one of the pins in the fastening configuration. In this regard, the activating element can translate the movement of the pin relative to the moving socket from the contact surface to the clamping configuration. For example, the movement of the pins can be converted into rotational movement of the contact surface in a juxtaposition relationship with the fixed pin. The apparatus may additionally include a release member for moving the fastening member into the release configuration. For example, the release member may be operated by a user by squeezing or sliding a plug housing member.

[00010] According to another aspect of the present invention, a method for using a fastening device is provided. The clamping device includes a clamping member and an activating member as described above. The user can activate the clamping device by inserting the pins of the male assembly into the sockets of the female assembly. In this coupled arrangement, the electrical connection is fixed as described above. The user may additionally deactivate the fastening device by forcing the fastening element into the release configuration, for example, by compressing the housing of the male assembly. In this way, the electrical connection can be simply clamped and released as desired by the user. BRIEF DESCRIPTION OF THE DRAWINGS Figures 1A-1C illustrate the operation of one embodiment of a clamping mechanism. Figures 2A-2B illustrate one embodiment of a locking electrical socket. Figures 3A-3B illustrate an application for the locking electrical socket shown in Figures 2A-2B. Figures 4A-4C illustrate an apparatus for providing a locking feature for a standard socket. Figure 5 illustrates one embodiment of a standard duplex locking socket. Figures 6A-6B illustrate an embodiment of a locking socket that includes a cam lock. Figures 7A-7D illustrate one embodiment of a device for locking a mating assembly of a plug and socket. Figures 8A-8B illustrate a plug embodiment that includes a locking mechanism. Figures 9A-9B illustrate another embodiment of a plug that includes a locking mechanism.

DETAILED DESCRIPTION

[00011] Although the invention is susceptible to various modifications and alternative forms, its specific embodiments have been shown by way of example in the drawings and are described in detail here. It must be understood, however, that it is not intended to limit the invention to the specific form described, but, more properly, the invention must cover all modifications, equivalents, and alternatives, falling within the spirit and scope of the invention as defined by the claims.

[00012] Figures 1A-1C illustrate the operation of an embodiment of a clamping mechanism for securing a coupling electrical connection that can be included in a locking socket of the present invention. In each of Figures 1A-1C, the lower part represents a side view of a pin 16 and a fastening mechanism 12, while the upper part represents a perspective view. Referring first to Figure 1A, pin 16 of a plug is shown prior to insertion into a socket 10. Pin 16 may be a ground pin of a standard plug (e.g., an IEC 320 plug, a NEMA 5- 15, or similar) and can be of different sizes and shapes. Additionally, socket 10 may be the ground socket of a model outlet (e.g., a NEMA standard cable cover, an IEC 320 cable cover, or the like) that is operative to receive a standard plug. The socket 10 also includes the clamping mechanism 12 which is coupled to a pivot 14. The clamping mechanism 12 includes an opening that is sized to be slightly larger than the pin 16, such that the pin 16 can pass only through of the opening when the length of the clamping mechanism is substantially perpendicular to the length of the pin 16. That is, the design of the clamping mechanism 12 is such that a simple slide and clamp technique is used.

[00013] Figure 1B illustrates pin 16 when inserted into socket 10. As shown, pin 16 passes through the opening in clamping mechanism 12 and into socket 10 such that the corresponding plug and socket are are in a mating position. The fastening mechanism 12 may additionally include a detent (not shown) to prevent the fastening mechanism 12 from rotating during insertion of the pin 16. In this regard, during the insertion of the pin 16, the length of the fastening mechanism 12 will remain substantially perpendicular to the length of the pin 16, which allows the pin to pass through the opening of the clamping mechanism 12.

[00014] Figure 1C illustrates the gripping function of the clamping mechanism 12 in reaction to a force on the pin 16 that tends to withdraw the pin 16 from the socket 10. In reaction to a removal of the pin 16, the clamping mechanism 12 is angularly deflected (i.e., rotates) about the pivot 14, causing the opening in the clamping mechanism 12 to grip the pins 16. Thus, the force tending to remove the pin 16 from the socket acts to actuate the clamping mechanism. fixing 12 to engage pin 16, thereby preventing removal of pin 16, and maintaining the electrical connection of the coupled assembly. The clamping mechanism 12 may be constructed of any suitable material, including a high strength dielectric material with a built-in metal gripping tooth. An all-metal clamping mechanism can also be used if pin 16 is a ground pin.

[00015] Figures 2A-2B illustrate a cross section of one embodiment of a locking electrical socket 20. Socket 20 is an IEC 320 type cable cover socket that includes a locking mechanism. The socket 20 includes an internal contact carrier module 24 that houses the contact sockets 26 and 28. Attached to the contact sockets are wires 36 and 38 that extend out of the socket 20 via a cable 34. The carrier module 24 may be attached to a cable strain relief means 32 that functions to prevent rupture of electrical connections when a force is applied to the cable 34. A spring-loaded pin retainer 40 is disposed adjacent to a surface of the carrier module 24 , and extends through a pin receiving portion 44 of the socket 20. One end of the spring-loaded pin retainer 40 is bent around the end of the internal contact carrier module 24, which secures it to the assembly. The other end is connected to a latch release gripping means 22. Similar to the clamping mechanism 12 shown in Figures 1A-1C, the spring-acting pin retainer 40 includes openings sized to allow passage of the ground pins. a plug into sockets 26. The openings in the spring-loaded pin retainer 40 may be sized to be slightly larger than one of the pins (e.g., the ground pin) on a standard plug such that the opening may function as the clamping mechanism for the locking socket 20. The operation of the clamping feature of the spring action pin retainer 40 is discussed in detail below.

[00016] Figure 2A illustrates the locking socket 20 when there is little or no tension on the cable 34. As shown, the spring-acting pin retainer portion 40 disposed in the pin receiving portion 44 of the socket 20 is not in a substantially vertical position. Similar to the operation of the clamping mechanism 12 shown in Figures 1A-1C, the spring-action pin retainer openings 40 in this configuration will allow the pins of a plug to pass freely into the sockets 26 when the pin is inserted. This is due to the unrestricted change of position of the spring action pin retainer 40 to the substantially vertical position when the pins of a plug act upon it.

[00017] Figure 2B illustrates the locking socket 20 when a force is applied to the handle 34 of the socket 20 in the opposite direction of the gripping release handle 30. This is the “release position” of the socket 20 and is shown without the mating pins for clarity of operation. The actions that initiate this position are illustrated in Figures 3A and 3B.

[00018] Figure 3A illustrates the operation of the electrical locking socket 20 shown in Figures 2A-2B. When a pin 54 of a socket 50 first enters the socket 20 through an opening in the latch release gripping means 22, it encounters the spring-loaded pin retainer 40, which is not in the perpendicular orientation at that time. Upon further insertion, the spring-acting pin retainer 40 is deflected into the perpendicular position through the force applied to it by the pin 54. The pin 54 passes through the opening in the spring-acting pin retainer 40 and stops. into contact socket 26, making the electrical connection as required. Upon release of the insertion force, and when no axial tension is applied to the coupled plug 50 and socket 20, the spring-acting pin retainer 40 is only partially displaced from the perpendicular axis.

[00019] Figure 3B illustrates in an exaggerated way the condition of applying axial tension to the cable 34 of the socket 20. Slight retraction movement pulls the spring action pin retainer 40, thereby increasing the gripping angle and subsequently the decreasing angle of travel of spring action pin retainer 40 and pin 54. Socket 20 and plug 50 are then completely locked in this condition. Upon application of axial tension between the release gripper cable 30 and the plug 50, the position of the spring-loaded pin retainer 40 is returned to the nearly perpendicular position, as illustrated in Figure 3A, thereby releasing the retainer. of spring action pin 40 from pin 54. Upon release, socket 20 is easily separated from plug 50.

[00020] By using a clamping mechanism (e.g., the spring-loaded pin retainer 40) that captures only the ground pin of the plug 50, the security of the socket 20 can be greatly improved. In this regard, the effect of applying various electrical potentials to the assembly's clamping mechanism is avoided, which can simplify the manufacturing of the socket as well as improve its overall safety.

[00021] Figures 4A-4C illustrate a locking device 60 for providing a locking feature for a standard socket. As shown in Figure 4A, the locking device 60 includes an upper retaining member 62 and a lower retaining member 64 for positioning the locking device 60 in a standard socket. The locking device 60 also includes a portion 66 that couples the retaining member 62, 64 relative to one another to provide secure attachment to a socket. The locking device 60 also includes a clamping mechanism 68 that is coupled to a pivot 70. The operation of the clamping mechanism 68 is similar to that of the clamping mechanism 12 illustrated in Figures 1A-1C. The locking device 60 may also include a release mechanism 72 that is operative to allow a user to disengage the locking mechanism 68 when it is desired to remove a socket from the plug.

[00022] Figure 4B illustrates the locking device 60 positioned in a standard socket 80. To facilitate installation of the locking device 60, the retaining members 62 and 64 may be made of an elastic material such that a user can flex them in an outward direction and position the device 60 in the socket 80. For example, the retaining members 62, 64 may be made of plastic. Additionally, as shown, the retention members 62, 64 are formed such that when installed in the socket 80, the device 60 is not easily removed without a user deforming the retention members 62, 64. That is, the retention members 62, 64 may be formed to fit closely into the standard socket such that normal movements will not disengage the device 60 from the plug 80.

[00023] Figure 4C illustrates the operation of the locking device 60 when the socket 80 is coupled with a standard plug 84. The ground pin 86 of the plug 84 passes through an opening in the clamping mechanism 68 and into the socket 80. If a removal force tending to break the union connection is applied to the standard plug cord 84 or the socket cord 80, the clamping mechanism 68 will rotate, causing it to grip the ground pin of the standard plug 84, thereby maintaining the electrical connection. If the user wishes to interrupt the connection, the user may engage the release member 72, which is operative to maintain the clamping mechanism 68 in a substantially perpendicular position with respect to the ground pin 86, thereby allowing the pin 86 of the plug to pattern 84 is removed from socket 80. It should be considered that although a specific embodiment of a locking device 60 has been illustrated, there may be several ways of implementing a locking device that can be upgraded to a standard socket utilizing the techniques herein. invention.

[00024] Figure 5 illustrates one embodiment of a standard duplex locking socket 100. In this embodiment, clamping mechanisms 112 and 114 are integrated into socket 100. The top of socket 100 includes sockets 102, 104 for receiving pins 128 , 130, respectively, of a standard plug 126. Similarly the bottom of the socket 100 includes sockets 106, 108 for receiving a second standard plug. The clamping mechanisms 112, 114 can be individually pivoted about the pivots 116, 118 respectively. Additionally the socket 100 also includes release elements 120, 122 which are operative to allow a user to terminate the connection when desired. The operation of the clamping mechanism 112, 114 is similar to that in previously described embodiments. That is, in response to a force tending to remove the plug 126 from the socket 100, the clamping mechanism 112 rotates toward the plug 126, and engages with the ground pin 130, preventing the union connection from being interrupted. . If a user wishes to intentionally remove the plug 126 from the socket 100, the user can activate the release mechanism 120 and remove the plug 126.

[00025] Figures 6A-6B illustrate side views of a socket 150 that includes a cam lock 152 for locking the pin 162 of a plug 160 to preserve a union connection between the socket 150 and the plug 160. Figure 6A illustrates the socket prior to insertion of the plug 160, and the cam lock 152 may be freely suspended from a pivot 153. In this regard, one end of the cam lock 152 is positioned in the opening of the socket 150 which is adapted to receive the pin 162 of plug 160.

[00026] Figure 6B illustrates the mating connection of plug 160 and socket 150. As shown, in the mating position, pin 162 has deflected cam lock 152 around pivot 153, causing cam lock 152 to be inclined away from plug 160 and contiguous to pin 162. Thus, when axial tension is applied to plug 160 or socket 150, friction between cam lock 152 and pin 162 will tend to force cam lock 152 in the direction toward down toward pin 162, which functions to retain plug 160 in its mating position. If a user wishes to intentionally remove the plug 160 from the socket 150, he may press the actuating mechanism 154, which may be operable to rotate the cam lock 152 out of the way of the pin 162, thereby allowing the user to withdraw freely. the plug 160 from the socket 150. It should be considered that the cam lock 152 and the drive mechanism may be constructed of any suitable materials. In one embodiment, the cam lock 152 is constructed of metal, and the drive mechanism 154 is constructed of an insulating material, such as plastic.

[00027] Figures 7A-7D illustrate a device 170 that can be used to secure a union connection between a plug and a socket. As shown, the device 70 includes an upper surface 173, a lower surface 175, and a front surface 171. The three surfaces 171, 173, 175 are generally sized and oriented to fit around the exterior of a standard socket 178 at the end of a cable (i.e. a cable cover). The upper and lower surfaces 173 and 175 include hooks 174 and 176, respectively, which are used to secure the device 170 in the socket 178 (shown in Figure 7D). The operation of the hooks 174 and 176 is described herein with reference to Figure 7D, which shows a side view of the device 170 when it is installed around the exterior of the socket 178. The hooks 174, 176 can be flexed inwardly in toward each other, and wrapped around one end 179 of the socket 178 to secure the device 170 to the socket 178. The other end of the socket 178 (i.e., the end with the openings 181 for receiving the pins of a plug) may be contiguous to the face surface 171 of the device 170.

[00028] The device additionally includes tabs 172 that are used to secure the pins of a plug in place. The operation of the tabs 172 is best shown in Figure 7B, which illustrates the device 170 when installed on the pins 182, 184 of a plug 180. The plug 180 can be any plug that includes pins, including typical plugs that are arranged on the back. of the electrical data processing device. As shown, when the device 170 is installed by sliding it axially toward the plug 180, the tabs 172 are deflected slightly toward the ends of the pins 182, 184. In this regard, if an axial force tends to withdraw the device 170 of the plug 180 is applied, the tabs 172 will apply a downward force against the pins 182, 184. Since the openings in the device 170 are only slightly larger than the pins 182, 184, this downward force retains , the pins 182, 184 in their positions relative to the device 170. Additionally, as the device 170 can be attached to a standard socket as illustrated in Figure 7C, the tabs 172 prevent the connection between the socket 178 and the plug 180 from being broken. Device 170 may be constructed of any suitable material. In one embodiment, the device 170 is constructed of a semi-rigid plastic. In this regard, the device 170 may be a single-use device in which a user must forcibly remove the installed device 170 from the pins 182, 184 of the plug 180, thereby deforming the plastic and/or breaking the tabs 172. It should be considered that if a user wishes to unplug the socket 178, he can simply unwind the hooks 174, 176 from the end 179 and separate the union connection, leaving the device 170 installed in a plug.

[00029] Figures 8A-8B illustrate a plug 190 that includes a locking mechanism prior to insertion into a socket 210. As shown in a simplified manner, socket 210 includes recesses 212 and 214. Most standard sockets include a recess or boss within openings that are adapted to receive the pins of a plug. This recess may be present due to manufacturing requirements, such as the molding process used to manufacture the sockets. Additionally, the need to include multiple components (e.g., electrical connections, screws, etc.) in sockets may cause the need for smaller sockets.

[00030] Plug 190 uses recess 214 to help create a locking mechanism. As shown, a hollow pin 194 (e.g., the ground pin) of the plug 190 includes a tab 196 that is pivotally secured to an internal portion of the pin 194. A spring 198 and a drive mechanism 200 work together to allow the tab 196 is oriented in a locking configuration (shown in Figures 8A-8B), and in a releasing configuration. In one embodiment, spring 198 acts to urge pawl 198 into the release position, which may be a substantially horizontal position within pin 194. Additionally, drive mechanism 200 may be operable to rotate pawl 196 to the position (shown in Figures 8A-8B) where the tab 196 projects outward from the pin 194 at an angle toward the body of the pin 190. A user can control the drive mechanism 200 through a control circuit breaker 202 which can be positioned in front of the 190 plug.

[00031] Figure 8B illustrates the plug 190 when in a mating position with the socket 210. As shown, the tab 196 has been placed in the locking position by the drive mechanism 200. In this configuration, the tab 196 will resist any axial force which tends to remove the plug 190 from the socket 210. This is the case because the recess 214 acts as a detent for the tab 196. Therefore, the plug 190 can be securely fixed to the socket 210. When a user wishes to remove the plug 190 of socket 210, it can toggle control circuit breaker 202 in front of plug 190, which causes drive mechanism 200 and spring 198 to rotate pawl 196 to the release position.

[00032] Figures 9A-9B illustrate another embodiment of a plug 220 that includes a locking mechanism prior to insertion into a socket 240. Similar to the plug 190 shown in Figures 8A-8B, the plug 220 can be adapted to work with the standard socket 240 that includes recesses 242 and 244. Plug 220 may include a fork spring 226 that is disposed within a hollow pin 224 (e.g., the ground pin). In a release position, the ends 227 of the spring 226 are disposed within the pin 224 and adjacent to the openings in the pin 224. The plug 220 may additionally include a drive mechanism 228, coupled to a control circuit breaker 230 in front of the plug 220 to bias the spring 226 to a locking position where the ends 227 of the spring 226 project out of the openings in the pin 224 (see Figure 9B).

[00033] Figure 9B illustrates the plug 220 when installed in the standard plug 240. As shown, the drive mechanism 228 has been displaced axially toward the spring 226, causing the ends 227 to separate and exit the openings in the pin 224. The pin openings 224 are aligned with the recesses 242 and 244 such that the ends of the spring 226 are disposed in the recesses 242 and 244 when in the locked position. Thus, as can be seen, when an axial force tending to withdraw the plug 220 from the socket 240 is applied, the ends 227 of the spring 226 are pressed against the recesses 242 and 244, which prevents the pin 224 from being removed from the socket. 240. When a user wishes to remove plug 220 from socket 240, he can operate control circuit breaker 230 which causes the drive mechanism to withdraw axially from spring 226. In turn, this causes the ends 227 of spring 226 recoil back onto pin 224 such that the user can then easily remove plug 220 from socket 240.

[00034] The previous description of the present invention has been presented for the purpose of illustration and description. Additionally, the description is not intended to limit the invention to the form described herein. Accordingly, variations and modifications compatible with the above teachings, and knowledge and practice of the relevant art, are within the scope of the present invention. The embodiments described above are further intended to explain the best known modes of practicing the invention and to permit others skilled in the art to utilize the invention in such or other embodiments and with various modifications required by the specific application(s) or use(s) of the invention. present invention. The appended claims are intended to be considered to include alternative embodiments to the extent permitted by the prior art.

Claims (22)

1. Apparatus for use in securing an electrical connection, the electrical connection being formed by a mating structure including pins (54) of a male assembly (50) and sockets (26, 28) of a female assembly, wherein the connection Electricity is interrupted by removing the pins from the sockets, the apparatus comprising: a locking socket (20) comprising: a clamping mechanism (12, 40) comprising an opening sized to permit passage of a pin into a socket , wherein the clamping mechanism is movable between a release position in which the clamping mechanism is arranged to permit separation of the male assembly from the female assembly, and a locking condition in which the clamping mechanism is arranged to maintain the connection electrical, wherein the clamping mechanism is arranged to deflect angularly in reaction to a force on the pin which tends to withdraw the pin from the socket, thereby causing opening in the clamping mechanism to grasp the pin and thus prevent removal of the pin and keep the electrical connection in blocked condition; characterized in that the apparatus further comprises a lock release claw (22) arranged to contact the clamping mechanism, wherein the lock release claw comprises a lock release cable (30) disposed on two opposite sides of the lock socket. locking; and wherein when the clamping mechanism is in the locked position, application of an axial tension between the lock release cable and the male assembly causes the clamping mechanism to release the pin so that the male assembly separates from the female assembly . 2. Apparatus according to claim 1, characterized by the fact that the clamping mechanism is operative to exert a clamping force on at least one of the pins. 3. Apparatus according to claim 1, characterized by the fact that the clamping mechanism is operative to exert a clamping force on a ground pin maintained at ground potential. 4. Apparatus according to claim 1, characterized in that the clamping mechanism includes a contact surface for contacting one of the pins in the locked condition, and is operative to translate the withdrawal movement of the moving pins of the surface contact. 5. Apparatus, according to claim 4, characterized by the fact that the fixing mechanism translates the movement of removing the pin into movement of the contact surface having a component transverse to the movement of the pin. 6. Apparatus, according to claim 4, characterized by the fact that the fixing mechanism translates the movement of removing the pin into a rotational movement of the contact surface. 7. Apparatus according to claim 1, characterized in that the apparatus is integrated into a standard electrical socket. 8. The apparatus of claim 1, wherein the apparatus is integrated into a standard cable cover socket. 9. The apparatus of claim 1, wherein the apparatus is adapted to fit a standard cable cover socket. 10. Method for use in securing an electrical connection, the electrical connection being formed by a mating structure including pins (54) of a male assembly (50) and sockets (26, 28) of a female assembly, wherein the connection is interrupted by removing the pins from the sockets, comprising the steps of: providing a locking socket (20) comprising a clamping mechanism (12, 40) comprising an opening sized to allow the passage of a pin into a socket, wherein the clamping mechanism is movable between a release position in which the clamping mechanism is arranged to permit separation of the male assembly from the female assembly, and a locking condition in which the clamping mechanism is arranged to maintain the electrical connection, in that the clamping mechanism is arranged to deflect angularly in reaction to a force on the pin which tends to withdraw the pin from the socket, thereby causing opening in the clamping mechanism to grasp the pin and thus prevent removal of the pin and maintain the connection electrical in blocking condition; activate the fixing mechanism by applying a force to the pin that tends to release the pin from the socket; and releasing the clamping mechanism to exert tension between the lock release cable and the male assembly; characterized in that the method further comprises the step of providing a lock release claw (22) for contacting the fastening mechanism, wherein the lock release claw comprises a lock release cable (30) disposed on two opposite sides of the locking socket, and wherein when the clamping mechanism is in the locked position, application of axial tension between the lock release cable and the male assembly causes the clamping mechanism to release the pin so that the male assembly separate from the female set; 11. Method, according to claim 10, characterized by further comprising the step of deactivating the clamping mechanism by forcing the clamping mechanism to the release position and interrupting the connection by removing the pins from the sockets. 12. The method of claim 11, wherein the disabling step includes pulling the lock release cable in the same direction as removing the pins. 13. Method according to claim 10, characterized by the fact that the clamping mechanism is operative to exert a clamping force on at least one of the pins. 14. Method according to claim 10, characterized by the fact that the clamping mechanism is operative to exert a clamping force on a ground pin maintained at ground potential. 15. Method according to claim 10, characterized by the fact that the clamping mechanism includes a contact surface for contacting one of the pins in the locking position, and is operative to translate the withdrawal movement of the moving pins of the surface contact. 16. Method, according to claim 15, characterized by the fact that the clamping mechanism translates the movement of removing the pin into movement of the contact surface having a component transverse to the movement of the pin. 17. Method, according to claim 15, characterized by the fact that the fixing mechanism translates the movement of removing the pin into a rotational movement of the contact surface. 18. Method according to claim 10, characterized by the fact that the clamping mechanism is adapted for operation by a user so as to interrupt the connection when desired. 19. Method according to claim 10, characterized by the fact that the fastening mechanism is released by movement of the lock release cable in the same direction as the movement of removing the pins. 20. Method according to claim 10, characterized by the fact that the device is integrated into a standard socket. 21. Method according to claim 10, characterized by the fact that the apparatus is integrated into a standard duplex socket. 22. Method according to claim 10, characterized by the fact that the apparatus is adapted to fit into a standard socket.