Industry-wide, the design of power distribution systems is essentially captive to proprietary overcurrent protection devices. As such, secondary power distribution system components, made by data communication manufacturers, are limited to the form factors (i.e., defined and prescribed sizes and shapes) of the proprietary overcurrent protection devices. In view of the proprietary designs, the design of any secondary power distribution system is limited to the form factors required by the various respective proprietary overcurrent protection devices, therefore increasing the cost of the secondary power distribution systems. Accordingly, there remains a desire to standardize power distribution equipment to not be captive to proprietary designs, and thus reduce cost.
Overcurrent protection devices for distributing power to direct current (DC) equipment coupled to a rack are described herein. More specifically, this disclosure relates to overcurrent protection devices that have a cartridge for removeably receiving a TPA fuse which is directly couplable to a power input connection and a power output connection of a power distribution panel. This summary is provided to introduce simplified concepts of overcurrent protection devices, which are further described below in the Detailed Description. This summary is not intended to identify essential features of the claimed subject matter, nor is it intended for use in determining the scope of the claimed subject matter.
In an embodiment, an overcurrent protection device includes a cartridge for removeably receiving a TPA fuse. The cartridge may include a power input terminal and a power output terminal. When the cartridge is removeably received by a power distribution panel, the power input terminal and the power output terminal may directly couple to a power input connection and a power output connection of the power distribution panel. The directly coupled power input terminal and the directly coupled power output terminal may be void of an intermediate busbar arranged between the cartridge and the power distribution panel.
In an embodiment, an overcurrent protection device includes a cartridge. The cartridge may include a receptacle for removeably receiving a TPA fuse. The cartridge may include a power input bullet terminal connected to the receptacle and a power output bullet terminal connected to the receptacle. When the cartridge is removeably received by a power distribution panel, the power input bullet terminal may removeably couple with a power input connection of the power distribution panel and the power output bullet terminal may removeably couple with a power output connection of the distribution panel.
In another embodiment, an overcurrent protection device includes a cartridge. The cartridge may include a receptacle for removeably receiving a TPA fuse. The cartridge may include a cover arranged with the receptacle. The cover may be displaceable between an open position and a closed position. When in the closed position the cover protects the TPA fuse removeably received in the receptacle.
In another embodiment, an overcurrent protection device includes a cartridge. The cartridge may include a receptacle for removeably receiving a TPA fuse. The cartridge may include a mechanical alarm to indicate when the TPA fuse has blown from an overcurrent event. The mechanical alarm may include a member displaceable between a first position and a second position. When in the second position a portion of the member may extend a distance from the cartridge indicating the TPA fuse has blown from the overcurrent event.
The detailed description is set forth with reference to the accompanying figures. In the figures, the left-most digit(s) of a reference number identifies the figure in which the reference number first appears. The use of the same reference numbers in different figures indicates similar or identical items.
This disclosure is directed to overcurrent protection devices having a cartridge for removeably receiving a TPA fuse, where the overcurrent protection device directly couples to a power input connection and a power output connection of a power distribution panel, the directly coupled overcurrent protection device being void of an intermediate busbar arranged between the cartridge and the power distribution panel. Because the overcurrent protection devices directly couple to power input and power output connections of the power distribution panel, a user may quickly and easily configure the power distribution panel as desired without being captive to proprietary designs associated with the TPA fuse. Moreover, because overcurrent protection devices directly couple to power input and power output connections of the power distribution panel without using an intermediate busbar arranged between the cartridge and the power distribution panel, a higher density of TPA overcurrent protection devices is achieved as compared to a lower density of proprietary TPA overcurrent protection devices.
In another example, an overcurrent protection device includes a cartridge for removeably receiving a TPA fuse and the cartridge may include a power input bullet terminal connected to the receptacle and a power output bullet terminal connected to the receptacle. The power input bullet terminal may removeably couple with a power input connection of the power distribution panel and the power output bullet terminal may removeably couple with a power output connection of the distribution panel. Because the power input bullet terminal and the power output bullet terminal may removably couple with the power output and power input connection of the power distribution panel, a user may quickly and easily populate the power distribution panel with TPA fuses and at a higher density. Moreover, because the power input bullet terminal and power output bullet terminal removably couple with the power output and power input connections of the power distribution panel similar to power input bullet terminals and power output bullet terminals of circuit breakers, a user may quickly and easily populate the power distribution panel with fuses and/or circuit breakers as desired.
In one example, components 108 may be pieces of telecommunications equipment in a telecommunication network infrastructure that may be kept or maintained in the rack 104 (e.g. cabinet) within the telecommunication network infrastructure. In another example, components 108 may be pieces of equipment in a solar power infrastructure that may be kept or maintained in the rack 104 within the solar power infrastructure. Specific examples of components 108, may include fiber optic equipment, switches, digital cross connect (DSX) systems, telecommunication panels, terminal blocks, digital radios, network office terminating equipment, cross-connect panels, modules, splitters, combiners, backplanes, repeaters, and any other telecommunication equipment or devices employed in a telecommunications infrastructure. Generally, components 108 may be those devices utilized for processing and distributing signals in infrastructure and which may be maintained in the rack 104. Components 108 may terminate, interconnect, or cross-connect a plurality of network elements within infrastructure. For example, components 108 may be utilized to distribute telecommunications signals sent to and from the infrastructure by one or more end-users using an end-user device. The interconnections between telecommunications equipment provide signal pathways for telecommunications signals (e.g., optical signals, electrical signals, digital signals, and/or analog signals). Interconnection may be via one or more components 108, such as by adapters on a module, connectors on a module, or may be internal to the components 108, such as via a printed circuit board within a component 108. With respect to the power distribution panel 106, each component 108 may be considered a load.
Front view 100 illustrates a front plate 112 of the power distribution panel 106, and back view 102 illustrates a back plate 114 of the power distribution panel 106 opposite the front plate 112 of the power distribution panel 106. The front plate 112 of the power distribution panel 106 may be disposed proximate to a first portion (e.g., a front portion) of the rack 104. The front plate 112 may be a modular face plate assembly that can be configured for low, medium, and/or high current overcurrent protection devices. For example, the front plate 112 may be configured to receive low, medium, and/or high current overcurrent protection devices.
Front view 100 illustrates the power distribution panel 106 may have a plurality of overcurrent protection devices 116 removeably received in the front plate 112 of the power distribution panel 106. The plurality of overcurrent protection devices 116 may be configured to hold GMT “grasshopper” fuses, KTK, KLM, and/or snap breakers (e.g., low current overcurrent protection devices), TPS, TPA fuses and/or circuit breakers (medium current overcurrent protection devices), TPC and/or TLS fuses (e.g., high current overcurrent protection devices), etc., suitable for telecommunications applications. The power distribution panel 106 may include any number of plurality of overcurrent protection devices 116. For example, the power distribution panel 106 may removeably receive 10 overcurrent protection devices 116. In another example, the power distribution panel 106 may removeably receive 5, 15, 20, or any quantity of overcurrent protection devices 116. In an embodiment, the quantity of plurality of overcurrent protection devices 116 may be based at least in part on how many components 108 a rack 104 is configured to house.
Back view 102 illustrates the back plate 114 of the power distribution panel 106 may be disposed proximate to a second portion (e.g., a back portion) of the rack 104. In some examples, the back plate 114 may be a modular frame assembly. The modular frame assembly may include a modular frame, one or more first modules removably attached in the modular frame, and one or more second modules, different from the one or more first modules, removably attached in the modular frame. The one or more first modules may include one or more input modules to attach the power distribution panel 106 to one or more power input cables 118 and to one or more power return cables 120. The one or more power input cables 118 and the one or more power return cables 120 are attached to the primary power distribution system 110. The one or more second modules may include one or more output modules to attach the power distribution panel 106 to one or more power output lines 122 and to one or more power return lines 124. The one or more power output lines 122 and the one or more power return lines 124 are attached to one or more of the plurality of components 108. The one or more second modules (e.g., output modules) may be electrically interconnected with the plurality of overcurrent protection devices 116 (described in detail below).
In one example, the input modules 210 may include a low current input module via which the power distribution panel 202 receives about 125 amperes from the power input cables 118 and the power return cables 120 attached to the primary power distribution system 110. In another example, the input modules 210 may include medium current input modules via which the power distribution panel 202 receives about 300 amperes from the power input cables 118 and the power return cables 120 attached to the primary power distribution system 110. In another example, the input modules 210 may include high current input modules via which the power distribution panel 202 receives about 600 amperes from the power input cables 118 and the power return cables 120 attached to the primary power distribution system 110.
In one example, the output modules 212 may include low current output modules via which the power distribution panel 202 outputs about 30 amperes to the power output lines 122 and the power return lines 124 attached to the components 108. In another example, the output modules 212 may include medium current output modules via which the power distribution panel 202 outputs about 100 amperes to the power output lines 122 and the power return lines 124 attached to the components 108. In another example, the output modules 212 may include low and medium current output modules via which the power distribution panel 202 outputs about 30 amperes and 100 amperes to power output lines 122 and the power return lines 124 attached to the components 108. In another example, the output modules 212 may include high current output modules via which the power distribution panel 202 outputs about 250 amperes to power output lines 122 and the power return lines 124 attached to the components 108.
The plurality of overcurrent protection devices 214 may be a plurality of medium current overcurrent protection devices. For example, one or more of the plurality of overcurrent protection devices 214 may include a TPA fuse. In another example, one or more of the plurality of overcurrent protection devices 214 may include a circuit breaker. In another example, one or more of the plurality of overcurrent protection devices 214 may include a low current overcurrent protection device (e.g., GMT “grasshopper” fuse, KTK, KLM, and/or breaker). In another example, one or more of the plurality of overcurrent protection devices 214 may include a plurality of high current overcurrent protection devices (e.g., TPC and/or TLC fuse).
Each overcurrent protection device of the plurality of overcurrent protection devices 214 may have a width of about 0.745 inches, a height of about 1.495 inches, and a length of about 5.940 inches. Because each overcurrent protection device of the plurality of overcurrent protection devices 214 may have a width of about 0.745 inches, the power distribution panel 202 may have a higher density of about 0.745 inches per fuse than a lower density of about 1.197 inches per fuse of the proprietary overcurrent protection devices. For example, because of the proprietary overcurrent protection devices have an intermediate busbar arranged between a fuse cartridge and a power distribution panel, the proprietary TPA overcurrent protection devices have the lower density of about 1.197 inches per fuse than the higher density of about 0.745 inches per fuse of the power distribution panel 202. Because of the higher density of about 0.745 inches per fuse, the power distribution panel 202 may be capable of removeably receiving about sixteen (16) overcurrent protection devices 214.
The power input connections 304 and power output connections 306 may directly couple to power input terminals and power output terminals of the overcurrent protection devices 302. The power output connections 306 may be connectable ends of the internal power lines 220. For example, the power output connections 306 may be female coupling ends of the internal power lines 220 that are fixed in the busbars 216 and removeably couple with the power output terminal. The directly coupled power input terminals and power output terminals being void of an intermediate busbar arranged between the overcurrent protection devices 302 and the power input connections 304 and power output connections 306 of the busbars 216. For example, each overcurrent protection device 302 may include a pair of power input and power output terminals that may cooperatively couple with a respective pair of the power input connection 304 and the power output connection 306 of the busbars 216 without the use of an intermediate busbar arranged between the overcurrent protection devices 302 and the busbars 216.
A user may quickly and easily removeably receive any one of the overcurrent protection devices 302 with the power distribution panel 202. For example, a user may quickly and easily slideably displace any one of the overcurrent protection devices 302 into the power distribution panel 202, and the user may quickly and easily slideably displace any one of the overcurrent protection devices 302 out of the power distribution panel 202. When the user slideably displaces one of the overcurrent protection devices 302 into the power distribution panel 202, the pair of power input and power output terminals of the overcurrent protection device 302 may slideably couple with a respective pair of the power input connection 304 and the power output connection 306 of the busbars 216. When the user slideably displaces one of the overcurrent protection devices 302 out of the power distribution panel 202, the pair of power input and power output terminals of the overcurrent protection device 302 may slideably decouple with a respective pair of the power input connection 304 and the power output connection 306 of the busbars 216. The overcurrent protection devices 302 may slideably displace linearly into and/or out of the power distribution panel 202 to cooperatively couple with a respective pair of the power input connection 304 and the power output connection 306 of the busbars 216.
The overcurrent protection device 402 may include a cartridge 412. The cartridge 412 may include a power input terminal 414 and a power output terminal 416. When the cartridge 412 is removeably received by the power distribution panel 202, the power input terminal 414 may directly couple to the power input connection 304 of the power distribution panel 202. The directly coupled power input terminal 414 being void of an intermediate busbar arranged between the cartridge 412 and the power distribution panel 202. When the cartridge 412 is removeably received by the power distribution panel 202, the power output terminal 416 may directly couple to the power output connection 306 of the power distribution panel 202. The directly coupled power output terminal 416 being void of an intermediate busbar arranged between the cartridge 412 and the power distribution panel 202. The power input terminal 414 may include a bullet type power input terminal and the power output terminal may include a bullet type power output terminal.
The cartridge 412 may include a mechanical alarm 418 to indicate when the TPA fuse 408 has blown from an overcurrent event. The mechanical alarm 418 may include a member 420 displaceable between a first position and a second position.
The cartridge 412 may have a top portion 426 and a bottom portion 428 opposite the top portion 426. In one example, the cover 404 may be slideably arranged in the top portion 426 of the cartridge 412. The cover 404 may be slideably arranged in the top portion 426 of the cartridge 412 for protecting the TPA fuse 408. While
A power input busbar 606 may be arranged in the cartridge 402 from the back portion 508 of the cartridge 402 toward the front portion 506 of the cartridge 402. The power input busbar 606 may have a first fastener 608 arranged in an end of the power input busbar 606 for removeably receiving a portion 610 of the TPA fuse 408. For example, the power input busbar 606 may have a clip arranged in the end of the power input busbar 606 for removeably receiving the portion of the TPA fuse 408.
A power output busbar 612 may be arranged in the cartridge 402 from the back portion 508 of the cartridge 402 toward the front portion 506 of the cartridge 402. The power output busbar 612 may have a second fastener 614 arranged in an end of the power output busbar 612 for removeably receiving another portion 616 of the TPA fuse 408. For example, the power output busbar 612 may have another clip arranged in the end of the power output busbar 612 for removeably receiving the other portion of the TPA fuse 408.
The first fastener 608 electrically connects the TPA fuse 408 to the power input terminal 414 and the second fastener 614 electrically connects the TPA fuse 408 to the power output terminal 416. The TPA fuse 408 may be removeably received into the first fastener 608 and the second fastener 614 via the receptacle 410 to complete the circuit. The power input terminal 414 may be fastened to a stud arranged in the end of the power input busbar 606. The power output terminal 416 may be fastened to a stud arranged in an end of the power output busbar 612.
The TPA fuse 408 may include an indicator pin 706 that extends from the TPA fuse 408 when the TPA fuse 408 has blown from an overcurrent event. The indicator pin 706 may extend from the portion 616 of the TPA fuse 408. For example, the indicator pin 706 may extend from the end of the TPA fuse 408 removeably received in the second fastener 614 of the power output busbar 612. A wire may retain the indicator pin 706 until the TPA fuse 408 experiences an overcurrent event. A spring may be arranged with the indicator pin 706 to force the indicator pin 706 to extend from the TPA fuse 408. When the TPA fuse 408 experiences an overcurrent event, the indicator pin 706 may extend from the end of the TPA fuse 408 and force the member 420 to move from the first position 422 to the second position 504. The TPA fuse 408 may be a 3 A (amperes) rated fuse, 5 A rated fuse, 10 A rated fuse, 15 A rated fuse, 20 A rated fuse, 25 A rated fuse, 30 A rated fuse, 40 A rated fuse, 50 A rated fuse, etc.
Although the invention has been described in language specific to structural features and/or methodological acts, it is to be understood that the invention is not necessarily limited to the specific features or acts described. Rather, the specific features and acts are disclosed as illustrative forms of implementing the invention. For example, while embodiments are described having certain shapes, sizes, and configurations, these shapes, sizes, and configurations are merely illustrative.