The present disclosure relates generally to circuit protection in communications system; more particularly, the present disclosure relates to an overvoltage protection plug usable in conjunction with a connection block.
Telecommunications systems generally include connection and disconnection systems, through which various types of telecommunications equipment are interconnected. Such systems generally require electrical protection, such as to prevent overvoltage and overcurrent events from damaging equipment, as can occur in the case of lightning strikes, power surges, or other electrical events. Various types of gas tube and solid state overvoltage protection components exist and are used in these telecommunications systems.
One piece of equipment used for connection of telecommunications systems is referred to herein as a connection block, sometimes referred to as a “Krone-style connector block”, such as those manufactured by ADC GmbH, formerly Krone GmbH. Such systems include a high density array of electrical connectors in a punch-down configuration, and are designed to accept overvoltage and overcurrent protection devices to protect the telecommunications equipment connected to the output side of the telecommunications circuit connected via the block. Because of the large number of wires being connected in a small area in a connection block, a small form factor circuit protection element is dictated. Other design requirements and failsafe protections may also limit the applicability of various gas tube and solid state protection devices. For example, gas tube overvoltage protection systems are disadvantaged in that, for higher voltage applications, the gas tube required increases in size. Additionally, cost reduction considerations require minimization of the number of components used.
The present disclosure relates generally to an overvoltage protection plug used in conjunction with a connection block. The overvoltage protection plug utilizes a gas tube rated sufficiently to meet various voltage safety certification requirements, and is configured to fit into a connection block while avoiding physical interference with neighboring circuit protection elements or connection locations.
According to a first aspect, an overvoltage protection plug is disclosed. The overvoltage protection plug includes a protection plug body formed from a chassis and a housing and defining an interior volume, the protection plug body including an insertion portion and a handle. The overvoltage protection plug further includes a gas tube located within the interior volume, the gas tube electrically connected to metallic leads protruding through the body at the insertion portion. The overvoltage protection plug also includes a grounding plate electrically connected to a ground pin of the gas tube.
According to a second aspect, a method of assembling an overvoltage protection plug is disclosed. The method includes mounting a gas tube to a chassis, and electrically connecting the gas tube to metallic leads, the metallic leads extending through the chassis. The method further includes inserting at least a portion of the chassis into a housing to form a body for the overvoltage protection plug, the body including an interior volume, and wherein the gas tube resides within the interior volume and the metallic leads extending through the chassis and are exposed external to the body. In certain cases, the method further includes filling the interior volume with gel, thereby environmentally protecting the interior volume of the overvoltage protection plug.
According to a third aspect, an overvoltage protection plug is disclosed. In this aspect, the overvoltage protection plug includes a protection plug body formed from a chassis and a housing and defining an interior volume, the protection plug body including an insertion portion and a handle. The overvoltage protection plug also includes a gas tube located within the interior volume and a plurality of metallic leads electrically connected to the gas tube, the plurality of metallic leads extending through slots in the chassis for electrical connection to a connection block. The overvoltage protection plug includes a grounding plate electrically connected to a grounding pin of the gas tube, and a gel surrounding the gas tube within the interior volume and arranged to protect the gas tube from environmental conditions surrounding the overvoltage protection plug.
According to a further aspect, an overvoltage protection plug is disclosed. The overvoltage protection plug includes a protection plug body formed from a chassis and a housing and defining an interior volume, the protection plug body including an insertion portion and a handle. The overvoltage protection plug also includes a gas tube located within the interior volume, the gas tube including electrically connected to conductive contacts within the interior volume, the conductive contacts protruding through the body at the insertion portion. The protection plug body includes a gel access opening for providing access to the interior volume.
According to a still further aspect, an overvoltage protection plug is disclosed. The overvoltage protection plug includes a chassis including an insertion portion arranged to be received into a connection block. The chassis includes a plurality of slots arranged to receive conductive leads, the slots extending through the chassis and oriented toward the insertion portion. The chassis further includes a grounding pin slot arranged to receive a grounding pin of a gas tube, and a guide member located between the slots and extending from the insertion portion. The chassis also includes a plurality of tabs defining a grounding plate mounting location on a top side of the chassis and a gel access opening extending through the chassis.
According to another aspect, a method of assembling an overvoltage protection plug is disclosed. The method includes electrically connecting each of a plurality of signal posts of a gas tube to conductive leads, the gas tube also including a grounding pin. The method further includes sliding the conductive leads through slots in the chassis and electrically connecting a grounding plate to the grounding pin on a side of the chassis opposite the gas tube. The method also includes inserting at least a portion of the chassis into a housing to form a snap-fit connection, the chassis and housing forming a body for the overvoltage protection plug. The method includes filling an interior volume of the overvoltage protection plug with gel through a gel access opening in the chassis, wherein the gel is arranged to protect the gas tube from environmental conditions.
Referring to
The plug 10 includes a body 12 formed from a chassis 14 and a housing 16. The body 12 has a top 13, bottom 15, right and left sides 18, 20, respectively. The body 12 also defines an insertion side 22 and a handle side 24 at opposite sides along its length. The size of the body 12 is minimized, at least with respect to the dimensions from the top 13 to bottom 15 and right to left (sides 18 and 20, respectively). This maximizes the circuit density of connection blocks in which the plug can be located. In one possible embodiment, the body 12 is approximately 0.31 inches wide by approximately 0.49 inches tall by approximately 1.44 inches long.
In the embodiment shown, two conductive contacts 26, 28 extend through the body at the insertion side 22, and are positioned to make contact with and electrically connect to electrical contacts in a high contact density connection block, such as a Krone-style connection block. Example Krone-style blocks useable in conjunction with the plug 10 are disclosed in German Patent No. DE3728368 and German Patent Application No. DE10001553. Additional details are described in U.S. Pat. Nos. 7,147,412; 7,008,243; 5,494,461; 5,163,855; 5,033,974; and 4,871,330, the disclosures of which are hereby incorporated by reference in their entireties.
The chassis 14 and housing 16 interconnect to form the body 12 via a snap-fit arrangement, in which tabs 30 arranged on a portion of the chassis inserted into the housing fit within openings 32 in the housing. Other arrangements for interconnecting the chassis 14 and housing 16 are possible as well, such as use of an adhesive, fastener, or other structure. Additional details of the chassis and housing are discussed below in conjunction with
Referring now also to
The gas tube 36 is electrically connected to the conductive contacts 26, 28. In the embodiment shown, the conductive contacts 26, 28 can be electrically connected to the signal leads 38 of the gas tube via a soldered connection; however, solderless connection arrangements are possible as well.
The gas tube 36 also electrically connects to a grounding plate 42. The grounding plate 42 is held apart from the gas tube 36 by a portion of the chassis 14, which allows the grounding pin 40 of the gas tube 36 to slide through the chassis to a mounting position. A grounding opening 44 in the body 12 allows external access to the grounding plate, to allow electrical connection of the grounding plate to a ground bar, such as a grounding bar associated with a connection block.
A gel access opening 46 extends through the body 12 as well. The gel access opening 46 allows access to the interior volume 34 of the plug 10. A gel can be added into the interior volume 34 to environmentally protect components within the interior volume 34. The gel access opening 46 generally allows gel to be provided into the interior volume 34 to a predetermined volume, such as the predetermined fill level 41 shown in
Referring now to
The chassis 14 includes slots 52 extending through the chassis 14 from the interior portion 50 toward left and right sides of the insertion portion 48. The slots 52 are sized to receive the conductive contacts 26, 28, which are exposed at the insertion portion 48 external to the body 12 while electrically connecting to the gas tube 34 within the interior volume 34. The insertion portion 48 also includes a central guide extension 49 that physically and electrically separates the conductive contacts 26, 28.
The chassis also includes a central pin receiving slot 54 normal to the slots 52 and arranged to accept insertion of the grounding pin 40 of the gas tube 36, for connection to the grounding plate 42. Tabs 56 on a top side of the chassis 14 define a mounting location for the grounding plate, and retain the grounding plate 42 in place when the overvoltage protection plug 10 is assembled. In the embodiment shown, the chassis 14 includes the gel access opening 46 located below the insertion portion 48, as previously described.
Referring now to
The housing 16 includes tab receiving openings 32 near the opening 35 that are configured to receive the tabs 30 of the chassis to form a snap-fit connection. The openings 32 are generally numbered and positioned in a manner complementary to the tabs 30, such that each tab has a corresponding opening.
The housing 16 defines a handle 60 shaped to be manually gripped for insertion and removal of the overvoltage protection plug 10 from a socket, connection block, or other insertion location. The handle 60 includes a plurality of ridges 61 to assist with manual gripping of the plug 10. The handle 60 can also be shaped to accept use of a punch down tool for insertion or removal of the plug 10. For example, the handle can include a hook-shaped portion for receiving a portion of such a tool. The punch down tool (not shown) can be used to insert or remove the overvoltage protection plug 10, due in part to the sizing and positioning of the handle 60 at the handle portion of the housing 16, extending rearwardly from the plug. As described above, an example punch down tool can be any of a variety of tools include a gripping portion (for example, a hook), such as a punch down tool distributed by ADC Krone GmbH. An example punch down tool is described in U.S. Pat. No. 4,434,542, the disclosure of which is hereby incorporated by reference in its entirety.
Referring now to
The gas tube 36 can be any of a variety of sizes. In various embodiments, the gas tube 34 is a gas discharge tube rated to meet electrical specifications of Underwriter's Laboratories, Telcordia, or another electrical safety specification appropriate to the region in which the plug 10 is used. Such gas discharge tubes can be any of a number of gas tubes manufactured by Bourns or other gas discharge tube manufacturer. In the embodiment shown, the gas tube has a diameter of approximately 5 mm. However, other sizes of gas tubes may be used as well to ensure that the necessary electrical specifications are met for use of the plug 10.
Optionally, the gas tube 36 includes a melt element 62 along the length of the tube. The melt element operates to permanently connect the signal leads 38 to the grounding pin 40 if a prolonged overvoltage event is detected. In the case of such an event, the gas tube 36 is activated for a long period of time, causing the temperature of the gas tube to rise, melting the melt element and causing a short circuit between the signal leads 38 and the grounding pin 38.
Now referring to
Referring now to the disclosure generally, to construct an overvoltage protection plug 10 such as is disclosed herein, an example process follows. A manufacturer can mount a gas tube to a chassis, such as by sliding one or more pins of the gas tube (e.g. the grounding pin 40 or signal leads 38) into a slot of the chassis arranged to accommodate the gas tube. Metallic leads, such as the conductive contacts 26, 28, are electrically connected to the signal leads 38 of the gas tube 36, and inserted through slots in the chassis to extend toward an insertion side of the chassis. For example, the conductive contacts 26, 28 can be soldered to the signal leads 38 of the gas tube 36.
A grounding plate 42 is electrically connected to the grounding pin 40 of the gas tube 36. The grounding plate is installed over the grounding pin, optionally such that a portion of the chassis 14 resides between the grounding plate 42 and the gas tube 36.
The interior portion 50 of the chassis 14, including the installed gas tube 36, grounding plate 42, and portions of the conductive contacts 26, 28, is inserted into the housing 16 to form a snap-fit connection, forming the overvoltage protection plug 10. The interior volume of the formed plug 10 can be filled with a gel, such as by inserting the gel through a gel access opening in the body 12 of the plug. The gel surrounds the grounding plate 42, conductive contacts 26, 28, and gas tube 36, to environmentally protect the electrical components from moisture or other harmful external conditions.
In operation, the overvoltage protection plug 10 is inserted into a connection block, thereby connecting two sets of contacts for a differential signal pair routed through the connection block. The overvoltage protection plug 10 detects overvoltage events, representing instances in which the voltage difference across the differential pair exceeds an acceptable, preset threshold value. When the voltage difference exceeds this threshold value (as determined by the specific voltage characteristics of the selected gas tube), one or both of the signal leads of the gas tube are shorted to the grounding pin of the gas tube, as described above in conjunction with
One example of a similar overvoltage protection plug that has analogous functionality is described in U.S. patent application Ser. No. 11/712,234, filed Feb. 28, 2007, and entitled “Overvoltage Protection Plug”, the entire disclosure of which is hereby incorporated by reference in its entirety.
Now referring to
In the embodiment shown, contacts 126, 128 replace contacts 26, 28 of
Additionally, a ground access opening 104 is located through the chassis 16 proximate to the protrusions 47, and allows connective test access to a grounding bar connected to the grounding plate 42 when the plug 100 is inserted into a connection block. In the embodiment shown, the ground access opening 104 extends through the chassis such that grounding access is available from either side of the plug 100.
Although certain particular methods of construction and operation of an overvoltage protection plug are described herein, other methods of construction and operation are possible as well. Furthermore, the various steps described to construct an overvoltage protection plug are not required to be performed in a specific order, and no order is imputed by this description.
Furthermore, it is noted that, although in the foregoing description of the overvoltage protection plug 10 terms such as, “top”, “bottom”, and “side” and words related thereto are used for ease of description and illustration, no restriction is intended by use of such terms. The plug 10 can be positioned in any orientation.
The above specification, examples and data provide a complete description of the manufacture and use of the composition of the invention. Since many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended.
The present application claims priority to U.S. Provisional Patent Application No. 61/056,328, filed May 27, 2008, the disclosure of which is hereby incorporated by reference in its entirety.
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