ANSI/TIA- 6. 06- B standard approved for publication. April, 2. 01. 2 Issue of Cabling Installation & Maintenance Magazine. Specification coves a wide range of labeling and administration procedures, including data center environments, grounding- and- bonding systems, powered data ports and more. By Todd Fries, Hellermann. Tyton. At last, the new ANSI/TIA- 6. B labeling standard has been approved by the Telecommunications Industry Association (TIA; www. Subcommittee TR- 4. Technical Engineering Committee TR- 4. American National Standards Institute (ANSI; www. While more than 3. TIA- 6. 06- A and then ANSI/TIA/EIA- 6. A Addendum 1. The standard is backward- compatible with the legacy ANSI/TIA/EIA- 6. A Addendum 1 and is compatible with the international standard ISO/IEC TR 1. The original TIA- 6. A was designated to identify and record the general administration, but did not address the specific needs of the data center design and installation. TIA- 6. 06- A was reaffirmed in 2. TIA- 6. 06- A Addendum 1 was published in 2. This great tutorial from LANshack.com goes step by step with pictures on how to terminate a Cat 5 patch cable and includes a how to video as well!The addendum reconciled 6. A with the TIA’s 9. In short, the current 6. Labeling is a key factor in the installation and maintenance of an efficient and professional installation. The 606 standard continues to expand and address how and where to identify key components of information transport. Buy cable: http:// Links: http:// How to play Rocksmith 2014 without original Realtone cable. Play Rocksmith with any soundcard. Play Rocksmith with any cable. Find great deals on quality fiber optic cables, network ethernet & computer cables, bulk fiber optic cables, media converters, testers and more at Cables Plus USA. Whether you call it a lead, a cord, or a cable, that shielded wire that links your guitar to your amp—and your music to your audience—is a vital link in your tone chain. The neat patch cable manager makes your cabling clean and simple! Get Free Shipping on neat patch kits with 24 or 48 cables. A did not really acknowledge data centers and the 9. The two concepts came together in Addendum 1 to 6. A. The development of the ANSI/TIA- 6. B, combined the 6. A and the Addendum 1, and unified the requirements of the ISO/IEC TR1. Labeling is a key factor in the installation and maintenance of an efficient and professional installation. The 6. 06 standard continues to expand and address how and where to identify key components of information transport systems (ITS). Changes from last revision. The ANSI/TIA- 6. 06- B standard includes several changes from the last revision of the specifications, including the following six major changes. Adopts identification scheme specified in TIA- 6. A Addendum 1. 2) Creates new identification format for Cabling Subsystem 1 link identifiers (Horizontal links), Cabling Subsystem 2 and 3 links (Backbone cables) as well as telecommunications outlets, equipment outlets, splices, consolidation points and outdoor telecommunications spaces. Campus cabling has its own cabling separate from the Cabling Subsystem 2 and 3 links, which are the two layers of backbone cabling allowed in premises cabling.)3) Extends administration to all inter- building telecommunications cabling. Administers Cabling Subsystem 2 and 3 links by pair groups, corresponding to ports rather than copper pairs or single fibers. Administration of grounding and bonding systems. Allows existing TIA- 6. A identifier formats to continue to be used where they are already in use. Only a portion of the identifiers is required to distinguish the component within the space in which it is located. You have no items in your shopping cart. Get Quote; My Wishlist; Custom Cable; MON - FRI: 8am - 5pm PST 1-888-275-8755. The basic premise of the data center implementation is actually very simple and can be broken down using a few common examples. A typical patch panel and port identifier might be as follows: 1. A. AD0. 2- 4. 0: 0. A. If we are on Floor 1, Space A, and this is the only space, there is no need to include that portion on the printed identifier. The actual printed identifier might look as follows: AD0. Because we are harmonizing to the ISO/IEC TR 1. The “+” sign only needs to appear in the records section and not on the actual label: +AD0. An “=” in front of an identifier specifies a function aspect (example: =XO for telecommunications outlet). Classes of administration. The standard still breaks out the criteria by classes of administration. Class 1—Locations served by a single Equipment Room (ER). This ER is the only Telecommunications Space (TS) administered, whereas there are no Telecommunications Rooms (TRs) and no Cabling Subsystem 2 and 3 cabling or outside- plant cabling systems to administer. Class 2—Completes the administration needs of a single building that are served by multiple TRs with one or more TRs within a single building. This includes all the elements of a Class 1 system plus identifiers for Cabling Subsystem 2 and 3 cabling, multi- element bonding and grounding systems and firestopping. Class 3—Serves a campus environment with multiple buildings and building pathways, spaces and outside- plant elements. Class 4—Attends the needs of a multi- site (multi- campus) administration. There are slight differences in requirements depending on what level is administered. For example, in a Class 1 system the floor and room number do not need to be identified because there is only one room to manage. Obviously, as the complexity of the system increases, additional identifiers are needed. In Class 3 and 4 systems there are additional requirements, such as building and campus identifiers, along with outside- plant and inter- campus elements such as wide area network connections. We will address these as well. Space, cabinets and racks. As an example of space labeling, 1. A = Floor 1, Space A, which is an alpha- numeric sequence that can be edited to suit the needs of the installation. For example, 3. TRA would represent Telecom Room A on the third floor. An example of an ISO/IEC TR 1. TRA. The standard recommends the use of grid coordinates to distinguish the rack or cabinet in a space. In rooms that have access- floor systems, recognition for the space shall employ the access- floor grid identification scheme using alpha and numeric characters to mark the X and Y coordinates within the space. To illustrate, a rack located at grid coordinates AD0. AD0. 2. Typically the label is placed on the top and bottom, front and rear of the rack or cabinet using machine- printed labels. Where grid coordinates are not used, the racks can be marked by row and rack number. Patch- panel and port identifiers. Within each rack, there will be patch panels. The patch panels shall be labeled with the identifier of the patch panels at the far end of the cables, if practical. These should be marked using rack units from the bottom of the cabinet. Because the floor/space marking is optional in a Class 2 system, the rack and panels can be marked simply by combining the grid coordinates of the rack with the rack units of the panels within that rack. A patch panel that is 3. AD0. 2 would be identified as AD0. The patch panels shall be labeled with the identifier of the patch panels at the far end of the cables, if practical. Each port, the first port or the last port, or the last of each subpanel, shall be labeled. Patch panel labels shall contain the patch panel identifier. Where space permits, the patch panel also should have labels to specify the classification at the far end ports using this format. Each panel will have a series of ports that need to be acknowledged. Thus, a typical patch panel/port identifier on a set of six ports within the patch panel might be marked as: AD0. AG0. 3- 3. 5 p 0. This defines the near- end set of six ports located in a patch panel 3. AD0. 2, and these ports are going to be the “far- end” set of six ports located in a patch panel 3. AG0. 3. Please note, the near- end room name and near- end patch panel identifier can be omitted because this information is implicit and inferred from the required cabinet/rack and patch- panel labels. Example: Ports 0. HDA0. 1 AJ1. 7- 4. Ports 0. 1- 0. 6. All ports on patch panels and all positions on termination blocks shall be labeled with the corresponding port number or position number and optionally with additional identifier fields as practical. All subpanels shall be labeled with their subpanel identifier. An example of a subpanel identifier usually is indicated by an alpha character, as in the following example. Ports A1- A6 & B1- B6 to AG1. B Ports 0. 1- 1. 2Ports A1- A6 = Subpanel A, ports A1- A6. Ports B1- B6 = Subpanel B, ports A1- A6. AG1. 0- B – Subpanel B in rack at grid location AG1. Ports 0. 1- 1. 2 – Ports 1 to 1. BCertain applications may provide electrical power in addition to data transmission over balanced twisted- pair cables. Visual identification of ports with power may be accomplished through the use of the symbol shown on page 1. This symbol can be included anywhere on the label. Specialized applications. The new standard does address unusual and constantly changing circumstances. For example, several manufacturers have come out with cabinets that use zero rack- mount space by incorporating vertical rails in the cabinet to save space. In short, additional patch panels reside on either side of the cabinet in a vertical position. In this case, how does one identify these vertical patch panels? A simple way to mark the vertical panels is to use rack units combined with an alpha character for location within the rack or cabinet. The TIA- 6. 06- B now designates an additional alpha letter indicating the side as A, B, C, D or F, L, R, B (Front, Left, Right, Back) as examples. This can be used when rack units (RU) are assigned. The user is able to name the horizontal and vertical patch panels by rack unit. The rack unit of the vertical patch panel is determined by the rack- unit location, of the height of the top of the vertically mounted patch (by height at the top). A separate alpha designation for Right (R) or Left (L) is used to distinguish the vertical patch panels as being either on the left or right side of the cabinet. Example: AG0. 9- L3. In this case, the credential is describing a patch panel at 3. AG0. 9, ports 1 to 6. Using preterminated copper or fiber solutions, zero- U, height- density cabinets can allow additional ports where needed and aligns connectivity with the servers. This allows for moves, adds and changes without interrupting rack- mounted equipment in a fully populated cabinet. This is a new trend in cabinet management to maximize data center real estate. Thankfully the new TIA- 6. B standard is flexible enough to allow proper identification of these vertical panels. Cabling Subsystem and Horizontal links. The main focus of the 6. B standard is the ability to track the ITS from the data center to the work area.
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