Patent Grant
11152745
The field of the disclosure relates generally to connector assemblies for electrical systems, and more particularly to tool-locking electrical plug and receptacle housings for use in hazardous environments.
Conventional connector assemblies are known to include a plug housing coupled to a receptacle housing with electrical contacts included inside. The receptacle housing includes a mounting shell having a bus bar installed inside. The bus bar is connected to an electrical panel of a power distribution system for supplying power to a load. A locking mechanism is mounted on the mounting shell and used to lock the plug housing with the receptacle housing.
In hazardous environments, such as refineries and petroleum chemical plants, ignitable gas, vapors or dust or otherwise flammable substances are present in the ambient environment of the connector assemblies. In such environments, additional safeguards are therefore required, including but not necessarily limited to securing electrical connections inside physically locked mating housing components to prevent human error and possible ignition risks associated with a disconnection of a circuit under load in the hazardous environment.
While known locking mechanisms are effective to provide the desired interconnections of plug housings with receptacle housings, they are prone to certain problems and improvements are desired.
Non-limiting and non-exhaustive embodiments are described with reference to the following Figures, wherein like reference numerals refer to like parts throughout the various drawings unless otherwise specified.
Conventional locking mechanisms providing locking of plug housings with receptacle housings in an electrical system are disadvantaged in certain aspects, especially in a hazardous environment. For example, locking mechanisms may be disengaged by a worker in disconnection of the electrical system, not realizing that the electrical contacts inside the plug and receptacle housings are energized, where any arc from disconnection could cause an explosion in the volatile atmosphere of the hazardous environment.
Electrical power systems sometimes operate within hazardous environments presenting a risk of explosion via ignition of a surrounding gas or vapor dusts, fibers, or flyings. Such hazardous environments may arise, for example only, in petroleum refineries, petrochemical plants, grain silos, waste water and/or treatment facilities among other industrial facilities, wherein volatile conditions are produced in the ambient environment and present a heightened risk of fire or explosion. A temporary or sustained presence of airborne ignitable gas, ignitable vapors or ignitable dust or otherwise flammable substances presents substantial concerns regarding safe and reliable operation of such facilities overall, including but not limited to safe operation of the electrical power system itself, which in some instances by virtue of conventional circuit protector devices may produce ignition sources in normal operation and in the presence of an electrical fault. As such, a number of standards have been promulgated relating to electrical product use in explosive environments to improve safety in hazardous locations in view of an assessed probability of explosion or fire risk.
For example, Underwriter's Laboratories (“UL”) standard UL 1203 sets forth Explosion-Proof and Dust-Ignition-Proof Electrical Equipment criteria for hazardous locations. Explosion-Proof and Dust-Ignition-Proof enclosures are available to enclose or contain electrical products. In combination with appropriate Explosion-Proof and Dust-Ignition-Proof enclosures, electrical equipment manufacturers may receive UL certification of compliance with the applicable rating standards for hazardous locations, and UL certification is an important aspect of a manufacturer's ability to successfully bring products to market in North America or any other market accepting of UL standard 1203.
The National Electric Code (NEC) generally classifies hazardous locations by class and division. Class 1 locations are those in which flammable vapors and gases may be present. Class II locations are those in which combustible dust may be found. Class III locations are those which are hazardous because of the presence of easily ignitable fibers or flyings. Considering Class 1, Division 1 covers locations where flammable gases or vapors may exist under normal operating conditions, under frequent repair or maintenance operations, or where breakdown or faulty operation of process equipment might also cause simultaneous failure of electrical equipment. Division 1 presents a greater risk of explosion than, for example, Division 2 where flammable gases or vapors are normally handled either in a closed system, confined within suitable enclosures, or are normally prevented by positive mechanical ventilation.
The International Electrotechnical Commission (IEC) likewise categorizes hazardous locations into Class I, Zone 0, 1, or 2 representing locations in which flammable gases or vapors are or may be airborne in an amount sufficient to produce explosive or ignitable mixtures. As defined in the IEC, a Class I, Zone 0 location is a location in which ignitable concentrations of flammable gases or vapors are present continuously or for long periods of time. A Class I, Zone 1 location is a location in which ignitable concentrations of flammable gases or vapors are likely to exist because of repair or maintenance operations or because of leakage or possible release of ignitable concentrations of flammable gases or vapors, or is a location that is adjacent to a Class I, Zone 0 location from which ignitable concentrations of vapors could be communicated.
Given that electrical devices, such as those described below, can be ignition sources in certain circumstances, explosion-proof, flame-proof, or ignition-proof enclosures are conventionally provided in NEC Division 1 or 2 locations and/or IEC Zone 1 or 2 locations to house electrical devices that pose ignition risk. The terms “explosion-proof” or “flame-proof” in this context, refer to enclosures that are designed to be capable of containing an internal explosion of a specified flammable vapor-air mixture.
Plug and receptacle housings disclosed herein are used to contain hazards and/or protect electrical contacts from exterior hazards. Plug and receptacle housings therefore are locked together and stay locked once a connector assembly is assembled. Under IEC Zone 2 standards, the use of a tooled feature is required to actuate the locking mechanism that locks a plug housing with a receptacle housing to prevent unplanned disengagement of the plug housing from the receptacle housing. Method aspects in this disclosure will be in part apparent and in part explicitly discussed in the following description.
In operation, plug housing 102 is coupled with receptacle housing 104 in connector assembly 100 shown in
In some embodiments, connector assembly 100 is weatherproof and provides a high level of indestructibility, which is suitable for hazardous environments. They are built to take heavy abuse and are resistant to wind, rain, mud, oil, and sea water, yet can be quickly connected and disconnected. Locking mechanism 106 locks plug housing 102 and receptacle housing 104 together, to prevent disruption of service and electrical shock hazards. Plug housing 102 and receptacle housing 104 are configured to receive and shield electrical contacts. Connector assembly 100 provides a safe high amperage connector, for example for carrying current having amperage as high as approximately 1030 A and/or alternating current or direct current (AD/DC) voltage of 1000 V.
In the exemplary embodiment, plug housing 102 includes a proximal end 202, where plug housing 102 is configured to be coupled with receptacle housing 104. Plug housing 102 further includes a distal end 204 opposite proximal end 202. Plug housing 102 has a first outer diameter 206 at proximal end 202. Plug housing 102 further includes a plug locking ring 208.
In the exemplary embodiment, plug locking ring 208 includes a groove 210 formed and positioned on an outer surface 212 of plug housing 102. Plug locking ring 208 has a second outer diameter 214 at groove 210. Second outer diameter 214 is measured at the lowest portion of groove 210. Plug housing 102 may have a third outer diameter 216 measured at the location of plug housing 102 adjacent to groove 210 at the side of groove 210 distal to proximal end 202. Third outer diameter 216 is larger than first outer diameter 206.
In the exemplary embodiment, receptacle housing 104 includes a mounting shell 302. Mounting shell 302 may include a mounting plate 304. Mounting plate 304 includes one or more mounting holes 306 (shown in
Mounting shell 302, for example, is made of aluminum. Mounting shell 302 may be made of other material that enables mounting shell 302 to function as described herein, including but not limited to stainless steel. Mounting shell 302 may also be epoxy powder coated. The coating of plug housing 102 and receptacle housing 104 may be color-coded for easy circuit identification when mating plug housing 102 with receptacle housing 104. Color coding also helps prevent reverse phasing on AC circuits or cross-polarization on DC circuits to assure correct rotation of motors while providing for operator safety. In the exemplary embodiment, cross-section 305 of mounting shell 302 at an end 316 is circular. Cross-section of mounting shell 302 may be in other shape that matches the shape of cross-section 201 of plug housing 102 and enables receptacle housing 104 to function as disclosed herein.
In the exemplary embodiment, locking mechanism 106 includes a latch 308 and a rod 310. Rod 310 is disposed inside receptacle housing 104. Rod 310 may be disposed in a groove 311 on a wall 313 of mounting shell 302. Rod 310 forms a circle, oval, ellipse, or other shapes having an inner diameter 307. Inner diameter 307 is measured at the narrowest portion of a shape 309 formed by rod 310 (see
In the exemplary embodiment, latch 308 includes a handle 318, and an anchor 320. Latch 308 couples to rod 310 at anchor 320. Latch 308 and rod 310 are made of stainless steel. Latch 308 and/or rod 310 may be made of other material that enables latch 308 and rod 310 to function as described herein, including but not limited to steel, copper, and brass. Latch 308 and rod 310 may be made of different material. Latch 308 may further include curved slots that ends of rod 310 follow when latch 308 rotates.
In operation, the locking and opening of the locking mechanism 106 is accomplished by rotation of handle 318. The rotation of handle 318 rotates rod 310 in and out such that diameter 307 of shape 309 formed by rod 310 changes. When locking mechanism 106 is at the locked position, rod 310 is constricted and closes in, and diameter 307 is decreased (shown in
To insert plug housing 102 into receptacle housing 104, locking mechanism 106 is at the open position. With diameter 307 of shape 309 formed by rod 310 larger than first outer diameter 206 of plug housing 102, plug housing 102 can be inserted into receptacle housing 104. Plug housing 102 may have third outer diameter 216 adjacent to groove 210 that is larger than first outer diameter 206 at proximal end 202, which can be used to stop plug housing 102 from being inserted too far into receptacle housing 104. Once rod 310 is disposed in plug locking ring 208 or plug housing 102 is stopped from being further inserted into receptacle housing 104, handle 318 is turned and rod 310 constricts to be positioned further into groove 210. As a result, locking mechanism 106 locks plug housing 102 and receptacle housing 104 together.
Because locking mechanism 106 locks and opens through rotation of latch 308, any worker can unlock plug housing 102 from receptacle housing 104 by rotating latch 308. In a hazardous environment, such a convenience can be dangerous because the electrical system is often energized and disconnection of an energized electrical system could cause an explosion due to arcs from disconnection. In the exemplary embodiments, locking mechanism 106 of connector assembly 100 further includes a tooled actuator 400, 500 (see
In operation, when locking mechanism 106 is locked, plunger 404 is aligned with aperture 402. A tool is inserted into aperture 402 to apply force onto plunger head 406 such that plunger head 406 springs up and is positioned in aperture 402 to lock locking mechanism 106. To unlock locking mechanism 106, the tool is inserted into aperture 402 to apply force on plunger head 406 such that plunger head 406 is pushed down and disengages from aperture 402. Accordingly, locking mechanism 106 does not become unlocked without the actuation of tooled actuator 400.
In operation, to lock locking mechanism 106 when it is at the locked position, set screw 504 is threaded into aperture 502 with a tool, with set screw 504 disposed inside aperture 502. To unlock locking mechanism, set screw 504 may be screwed out of or further into aperture 502 such that set screw 504 is outside aperture 502.
In the exemplary embodiment, method 600 may further include actuating the tooled actuator to unlock the locking mechanism and rotating the latch such that the locking mechanism is at an open position. Method 600 may include disengaging the plug housing from the receptacle housing when the locking mechanism is at the open position.
The configurations of the plug housing and receptacle housing may be reversed from the embodiments illustrated in another contemplated embodiment. That is, the receptacle housing may be inserted into a plug housing with a locking mechanism positioned on the outer surface of the plug housing.
Various embodiments of connector assemblies are described herein including a locking mechanism having a tooled actuator, where the tooled actuator locks and unlocks the locking mechanism and is actuated by a tool, thereby increasing the safety of connector assemblies, as well as complying with the IEC standards, e.g., IEC60079-15. Further, the locking mechanism is locked and unlocked by the rotation of a latch, thereby increasing the speed in assembling and dissembling connector assemblies.
The benefits and advantages of the inventive concepts are now believed to have been amply illustrated in relation to the exemplary embodiments disclosed.
An embodiment of a connector assembly for electrical contacts has been disclosed. The connector assembly includes a plug housing, a receptacle housing, and a locking mechanism. The plug housing is configured to receive a first electrical contact. The receptacle housing is configured to receive a second electrical contact that is configured to couple to the first electrical contact, the receptacle housing including a mounting shell. The locking mechanism is mounted on the mounting shell of the receptacle housing and configured to couple the plug housing with the receptacle housing, the locking mechanism including a latch. The locking mechanism transitions between a locked position and an open position by rotation of the latch. The receptacle housing is configured to engage with the plug housing when the locking mechanism is at the locked position. The receptacle housing is configured to disengage from the receptacle housing when the locking mechanism is at the open position. The locking mechanism further includes a tooled actuator configured to lock the locking mechanism when the locking mechanism is at the locked position, the tooled actuator sized to require a tool to operate the tooled actuator.
Optionally, the tooled actuator includes an aperture disposed through the latch and sized to require a tool to be inserted into the aperture to operate the tooled actuator. The tooled actuator further includes a plunger, the plunger further includes a plunger head sized to be received in the aperture, the plunger head is positioned in the aperture when the tooled actuator is actuated, and the plunger head is positioned outside the aperture when the tooled actuator is unactuated. The tooled actuator further includes a set screw having threads on its outer surface, and the aperture is sized to receive the set screw therein and further includes threads disposed on its wall that are complimentary to the threads of the set screw. The plug housing further includes a plug locking ring formed on an outer surface of the plug housing, the receptacle housing further including a rod positioned inside the mounting shell, and the rod and the plug locking ring configured to engage with each other when the locking mechanism is at the locked position. The plug locking ring includes a groove formed on the outer surface of the plug housing, the rod closes in and is disposed in the groove when the latch is at the locked position, and the rod relaxes back and disengages from the groove when the latch is at the open position.
Another embodiment of a connector assembly for electrical contacts is disclosed. The connector assembly includes a plug housing, a receptacle housing, and a locking mechanism. The plug housing is configured to receive a first electrical contact. The receptacle housing is configured to receive a second electrical contact that is configured to couple to the first electrical contact, the receptacle housing including a mounting shell. The locking mechanism is mounted on the mounting shell and configured to couple the plug housing with the receptacle housing. The receptacle housing is configured to engage with the plug housing when the locking mechanism is at a locked position. The receptacle housing is configured to disengage from the receptacle housing when the locking mechanism is at an open position. The locking mechanism further includes a tooled actuator configured to lock the locking mechanism when the locking mechanism is at the locked position, the tooled actuator sized to require a tool to operate the tooled actuator.
Optionally, the tooled actuator includes an aperture disposed through the latch and sized to require a tool to be inserted into the aperture to operate the tooled actuator. The tooled actuator further includes a plunger, the plunger further includes a plunger head sized to be received in the aperture, the plunger head is positioned in the aperture when the tooled actuator is actuated, and the plunger head is positioned outside the aperture when the tooled actuator is unactuated. The tooled actuator further includes a set screw having threads on its outer surface, and the aperture further includes threads on its wall that are complimentary to the threads of the set screw. The locking mechanism includes a latch and transitions between the locked position and the open position by rotation of the latch. The plug housing further includes a plug locking ring formed on an outer surface of the plug housing, the receptacle housing including a rod positioned inside the mounting shell, the rod and the plug locking ring configured to engage with each other when the locking mechanism is at the locked position. The plug locking ring includes a groove formed on the outer surface of the plug housing, the rod closes in and is disposed in the groove when the latch is at the locked position, and the rod relaxes back and disengages from the groove when the latch is at the open position.
One more embodiment of a connector assembly for electrical contacts is disclosed. The connector assembly includes a plug housing, a receptacle housing, and a locking mechanism. The plug housing is configured to receive a first electrical contact. The receptacle housing is configured to receive a second electrical contact that is configured to couple to the first electrical contact, the receptacle housing including a mounting shell. The locking mechanism is mounted on the mounting shell of the receptacle housing and configured to couple the plug housing with the receptacle housing, the locking mechanism including a latch. The locking mechanism transitions between a locked position and an open position by rotation of the latch. The receptacle housing is configured to engage with the plug housing when the locking mechanism is at the locked position. The receptacle housing is configured to disengage from the receptacle housing when the locking mechanism is at the open position.
Optionally, the locking mechanism further includes a tooled actuator configured to lock the locking mechanism when the locking mechanism is at the locked position, the tooled actuator sized to require a tool to operate the tooled actuator. The tooled actuator includes an aperture disposed through the latch, the aperture sized to require a tool to be inserted into the aperture to operate the tooled actuator. The tooled actuator further includes a plunger, the plunger further includes a plunger head sized to be received in the aperture, the plunger head is positioned in the aperture when the tooled actuator is actuated, and the plunger head is positioned outside the aperture when the tooled actuator is unactuated. The tooled actuator further includes a set screw having threads on its outer surface, and the aperture further includes threads on its wall that are complimentary to the threads of the set screw. The plug housing further includes a plug locking ring formed on an outer surface of the plug housing, the receptacle housing including a rod positioned inside the mounting shell, and the rod and the plug locking ring configured to engage with each other when the locking mechanism is at the locked position. The plug locking ring includes a groove formed on the outer surface of the plug housing, the rod closes in and is disposed in the groove when the latch is in the locked position, and the rod relaxes back and disengages from the groove when the latch is in the open position.
While exemplary embodiments of components, assemblies and systems are described, variations of the components, assemblies and systems are possible to achieve similar advantages and effects. Specifically, the shape and the geometry of the components and assemblies, and the relative locations of the components in the assembly, may be varied from that described and depicted without departing from inventive concepts described. Also, in certain embodiments certain components in the assemblies described may be omitted to accommodate particular types of electrical contacts or the needs of particular installations, while still providing cost effective connector assemblies for electrical wiring or cabling.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
This application claims the benefit of U.S. Provisional Application No. 62/851,337, filed May 22, 2019, the entire contents and disclosures of which are hereby incorporated by reference herein in their entirety.
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