HP Power over Ethernet (PoE/PoE+) Planning and Implementation Guide Power over Ethernet
Power over Ethernet (PoE/PoE+) Planning and Implementation Guide
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Contents 1 Introduction Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 Power Through the Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4 PoE Capabilities of the HP Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-5 HP ProCurve 2520 Switches . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-6 HP ProCurve 2520G Switches . . . . . . . . . . . . . . . .
ProCurve Switch zl 20 port Gig-T + 4 port mGBIC Module (J8705A) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HP ProCurve 24-Port 10/100/1000 PoE+ zl Module . . . . . . . . . . . . . . . HP ProCurve 20-Port 10/100/1000 PoE+/4 Port MiniGBIC zl Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HP ProCurve 24-Port 10/100 PoE+ zl Module . . . . . . . . . . . . . . . . . . . HP 24-Port Gig PoE+ v2 zl Module . . . . . . . . . . . . . . . . . . . . . .
PoE+ Power Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PoE/PoE+ Allocation Using LLDP Information . . . . . . . . . . . . . . HP ProCurve 2910al PoE+ Switches . . . . . . . . . . . . . . . . . . . . . . . . . . . Maximum PoE Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PoE Power Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PoE/PoE+ Allocation Using LLDP Information . . . . . . . . . . . . . .
5 Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ProCurve 2610-24/12PWR Configurations . . . . . . . . . . . . . . . . . . . . . . . ProCurve 2610-24-PWR Configurations . . . . . . . . . . . . . . . . . . . . . . . . . ProCurve 2610-48-PWR Configurations . . . . . . . . . . . . . . . . . . . . . . . . .
11 Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration . . . . . . . . . . . . . . . . . . . . . . . . . HP ProCurve 3500yl-24G-PWR Configuration . . . . . . . . . . . . . . . . . . . HP ProCurve 3500yl-48G-PWR Configuration . . . . . . . . . . . . . . . . . . . HP ProCurve 3500yl-24G-PoE+ Configuration . . . . . . . . . . . . . . . . . . HP ProCurve 3500yl-48G-PoE+ Configuration . . . . . . . . . . . . . . . . . .
Using the HP ProCurve 1500W PoE+ zl Power Supply (J9306A) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13-28 ProCurve 5412zl/8212zl Configurations using the Power Supply Shelf . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13-30 14 Infrastructure Requirements Air conditioning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-1 Power requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Introduction Overview 1 Introduction This chapter provides an overview of: ■ Power over Ethernet (PoE/PoE+). ■ A list of reasons why you might want to implement PoE in your network environment. ■ How PoE supplies power over twisted pair cable. ■ The capabilities of the devices used to provide PoE.
Introduction Overview The technology is bound to make a big impact in the world of embedded computing. In the realm of embedded computers, where the systems are increasingly connected to LANs and the internet, the advantages of providing power and data through a single cable should be obvious. Consider a typical application: a system for a multi-level car parking garage that includes security cameras, information signs, call-for-help telephones and vehicle sensors.
Introduction Overview Power over Ethernet connections to embedded computers will allow a less expensive installation (no AC cabling, lower labor costs), facilitate updating the installation and repositioning of end devices (wireless access points, security cameras, and so forth) without electricians, while maintaining full control over every node through the internet. Figure 1-1 shows a typical system implemented to power telephones and wireless access points.
Introduction Power Through the Cable Here are some reasons why you might want to do this: ■ Simplifies installation and saves space - only one set of wires to bring to your appliance. ■ Saves time and money - there is no need to pay for additional electrical power runs or to delay your installation schedule to make them. ■ Minimal disruption to the workplace - the appliance can be easily moved, to wherever you can lay a LAN cable. ■ Safer - no AC voltages need to be added for additional network devices.
Introduction PoE Capabilities of the HP Products An obvious requirement of the specification is to prevent damage to existing Ethernet equipment. A discovery process, run from the PSE, examines the Ethernet cables, looking for devices that comply with the specification. It does this by applying a small current-limited voltage to the cable and checks for the presence of a 25k ohm resistor in the remote device.
Introduction PoE Capabilities of the HP Products HP ProCurve 2520 Switches The 2520 (J9137A), has 8 Integrated PoE auto-sensing 10/100Base-TX RJ-45 ports with two dual-personality Gigabit Uplink ports. The 2520 (J9138A), has 24 Integrated PoE auto-sensing 10/100Base-TX RJ-45 ports and two 10/100/1000Base-TX uplink ports, with two dual-personality Gigabit Uplink ports. These switches also support some pre-standard PoE devices. For a list of these devices, see the FAQs for your switch model.
Introduction PoE Capabilities of the HP Products These switches also support some pre-standard PoE devices. For a list of these devices, see the FAQs for your switch model. This feature is enabled by default. The dual-personality ports have either auto-sensing 10/100/1000Base-T RJ-45 or mini-GBIC connectivity. The dual-personality ports do not support PoE.
Introduction PoE Capabilities of the HP Products *Spd mode: ProCurve Switch 2600-PWR J8762A Status RPS Power Fault EPS flash = 100 Mbps, on = 1000 Mbps Dual-Personality Port: 10/100/1000-T (T) or Mini-GBIC (M) PoE-Integrated 10/100-TX Ports (1 - 8) (Ports are HP Auto-MDIX) Link Act 1 Mode 2 3 4 Link 5 Mode 6 (Port 9T is IEEE Auto MDI/MDIX) 7 8 FDx Fan Spd Test PoE Reset off = 10 Mbps, PoE LED Mode Link 9T 9M Mode Link * Clear Console Mode ! Use only one (T or M) for
Introduction PoE Capabilities of the HP Products Power Redundancy for the 2600 and 2610 Switches The internal power supply in these switches provides both the 12V (RPS) and 50V (EPS) circuits. If either the 12V or 50V fails, the power supply shuts down which will bring down all switch and PoE connections. Therefore it is important to provide a redundant power supply for both the 12V and 50V circuits.
Introduction PoE Capabilities of the HP Products HP E2620-PoE+ Switches The HP Switch E2620-48-PoE+ (J9627A), has 48 Integrated PoE+ auto-sensing 10/100/1000Base-T RJ-45 ports with four Gigabit Uplink ports. The HP Switch E2620-24-PoE+ (J9625A), has 24 Integrated PoE+ auto-sensing 10/100/1000Base-T RJ-45 ports with two Gigabit Uplink ports. The HP Switch E2620-24-PPoE+ (J9624A), has 24 Integrated PoE+ autosensing 10/100/1000Base-T RJ-45 ports with two Gigabit Uplink ports.
Introduction PoE Capabilities of the HP Products Power Redundancy for the E2620 Switches The internal power supply in these switches provides both the 12V (RPS) and 54V (EPS) circuits. If the 54V portion of the power supply fails, it will only shut down the PoE connections. However, if the 12V portion of the power supply fails, it will shut down the entire switch. Therefore it is important to provide a redundant power supply for both the 12V and 54V circuits.
Introduction PoE Capabilities of the HP Products These switches also support some pre-standard PoE devices. While HP strives to support as many non-standard devices as possible, some devices in the market are designed in ways that are restrictive, or exclusive of the IEEE standard and thus cannot be supported. For a list of these devices, see the FAQs for your switch model at www.hp.com/networking/support, and click on faqs. This feature is the default and you must disable it if you do not want to use it.
Introduction PoE Capabilities of the HP Products HP ProCurve 2915G Switch The HP ProCurve Switch 2915-8G-PoE (J9562A), has 8 Integrated PoE autosensing 10/100/1000Base-TX RJ-45 ports with two dual-personality Gigabit Uplink ports. There is no power redundancy for this switch. These switches also support some pre-standard PoE devices. For a list of these devices, see the FAQs for your switch model. This feature is enabled by default.
Introduction PoE Capabilities of the HP Products HP ProCurve 3500-PoE Switches The HP ProCurve Switch 3500-48G-PoE (J9473A), has 44 Integrated PoE autosensing 10/100 Base-T RJ-45 ports and four ports of Gigabit dual-personality Uplink ports, either RJ-45 or SFP. The HP ProCurve Switch 3500-24G-PoE (J9471A), has 20 Integrated PoE autosensing 10/100 Base-T RJ-45 ports with four ports of Gigabit dual-personality Uplink ports, either RJ-45 or SFP. These switches also support some pre-standard PoE devices.
Introduction PoE Capabilities of the HP Products The HP ProCurve 3500-PoE Switches can be connected to a 620 RPS/EPS (J8696A) and receive full redundant power from the RPS part of the unit for switch operation if the internal power supply in the switch fails. If two switches are connected to the RPS ports and both switches lose power at the same time, they both receive redundant power. The 620 RPS/EPS unit can provide all the power necessary to keep two switches running.
Introduction PoE Capabilities of the HP Products Power Redundancy for the 3500yl PWR Switches The internal power supply in these switches provides both the 12V (RPS) and 50V (EPS) circuits. If the 50V portion of the power supply fails, it will only shut down the PoE connections. However, if the 12V portion of the power supply fails, it will shut down the entire switch. Therefore it is important to provide a redundant power supply for both the 12V and 50V circuits.
Introduction PoE Capabilities of the HP Products For more information, refer to the Management and Configuration Guide for your switch at www.hp.com/networking/support. The dual-personality ports have either auto-sensing 10/100/1000Base-T RJ-45 or mini-GBIC connectivity. The mini-GBIC ports do not support PoE. If any of the mini-GBIC ports are used the corresponding RJ-45 port will not be supplied with PoE power.
Introduction PoE Capabilities of the HP Products The HP E3800-48G-PoE+-4XG Switch (J9588A), has 48 Integrated PoE autosensing 10/100/1000Base-T RJ-45 ports with four XG ports. The E3800-24G-PoE+-2XG Switch (J9587A), has 24 auto-sensing 10/100/1000T RJ-45 ports and two XG ports. These switches also support some pre-standard PoE devices. For a list of these devices, see the FAQs for your switch model. This feature is disabled by default and must be enabled to use it.
Introduction PoE Capabilities of the HP Products HP E5400zl/E8200zl Switches The HP Switch E5406zl is a chassis that can hold up to six 24-port modules to provide up to 144 10/100/1000Base-T RJ-45 ports for PoE/PoE+ power. The HP Switch E5412zl is a chassis that can hold up to twelve 24-port modules to provide up to 288 10/100/1000Base-T RJ-45 ports for PoE/PoE+ power.
Introduction PoE Capabilities of the HP Products The HP Switch E8206zl is a chassis that can hold up to six 24-port modules to provide up to 144 10/100/1000Base-T RJ-45 ports for PoE/PoE+ power.
Introduction PoE Capabilities of the HP Products The HP Switch E8212zl is a chassis that can hold up to twelve 24-port modules to provide up to 288 10/100/1000Base-T RJ-45 ports for PoE/PoE+ power. Note The E5412zl chassis and the E8212zl chassis share a completely common PoE/PoE+ implementation. Port counts, power supply wattages, specifications, and functionality for these two platforms are the same with respect to PoE/PoE+.
Introduction PoE Capabilities of the HP Products The 12V system power is used to operate the internal components of the switch. The 50V PoE or 54V PoE/PoE+ power is used to power the PoE devices connected to the modules. It is important to provide a secondary power supply for redundancy purposes for both the 12V and 50V or 54V circuits. The internal power supply in these switches provides both the 12V (system) and 50V (PoE) or 54V (PoE+) circuits. If the 12V (system) power fails the switch will shut down.
Introduction PoE Capabilities of the HP Products PoE Chassis Power Supplies Note HP highly recommends that the two types of power supplies are not mixed in the same chassis. For PoE only, the following power supplies can be used: ■ ■ J8712A, which operates at 100-127 volts drawing a maximum of 11.5 amps, or 200-240 volts drawing a maximum of 5.
Introduction PoE Capabilities of the HP Products Configuring PoE Redundancy When considering redundant power, also consider the power source for the power supplies. Each power supply should be connected to a separate power source circuit in order to supply complete redundancy. Should one circuit fail, it would then be possible for the other circuit to continue supplying power to the second power supply in the switch, keeping the switch running.
Introduction HP ProCurve PoE and PoE+ Modules HP ProCurve PoE and PoE+ Modules HP ProCurve Switch xl PoE Module The HP ProCurve Switch xl PoE Module (J8161A) is a module for the HP ProCurve 5300xl Switch and has 24 PoE-ready auto-sensing 10/100-TX RJ-45 ports.
Introduction HP ProCurve PoE and PoE+ Modules ProCurve Switch zl 20 port Gig-T + 4 port mGBIC Module (J8705A) The ProCurve Switch zl 20 port Gig-T + 4 port mGBIC Module (J8705A) is for the HP E5400/E8200zl switches and has 20 PoE auto-sensing 10/100/1000-TX RJ-45 ports. All 20 ports are capable of supplying PoE power. Additionally there are four mini-GBIC/SFP ports, which do not supply PoE power.
Introduction HP ProCurve PoE and PoE+ Modules HP ProCurve 24-Port 10/100 PoE+ zl Module The HP ProCurve Switch zl PoE/PoE+ 24-port module (J9478A) is for the HP E5400zl/E8200zl switches and has 24 PoE/PoE+ auto-sensing 10/100-TX RJ-45 ports capable of providing PoE/PoE+ power.
Introduction HP ProCurve PoE and PoE+ Modules HP 20-Port PoE+ & 2-port SFP+ v2 zl Module HP Switch 20-port PoE+ & 2-port 10Gig SFP+ v2 zl Module (J9536A) is for the HP E5400zl/E8200zl switches and has 20 twisted-pair ports with RJ-45 connectors for 10/100/1000Base-T ports that support PoE+ and 2 ports for installing any of the supported HP SFP+ Transceivers. All RJ-45 ports have the IEEE 802.3ab Auto MDI/MDI-X (HP Auto-MDIX) feature and support PoE+. The SFP+ ports do not support IEEE 802.3at PoE+.
Introduction Quick Reference Table Quick Reference Table Model/ Device Port Type Port Count/ PoE watts per port1 Gig Uplink Ports RPS/EPS Maximum Power Internal and External 2520-8-PoE 10/100 8 4 @ 15.4 watts 8 @ 7.5 watts 22 N/A 67 watts available to ports 1-8 (provided by the internal source). 2520-24-PoE 10/100 24 12 @ 15.4 watts 24 @ 7.5 watts 4 2 - RJ45 only 22 N/A 195 watts available to ports 1-24 (provided by the internal source). 2520G-8-PoE 10/100/1000 8 4 @ 15.4 watts 8 @ 7.
Introduction Quick Reference Table Model/ Device Port Type Port Count/ PoE watts per port1 Gig Uplink Ports 2610-24-PWR 10/100 24 24 @ 15.4 watts 4 J8168A J8169A 406 watts available to ports 1-24 (provided by the internal source). 408/2044 watts available, provided by the EPS source. 2610-48-PWR 10/100 48 48 @ 15.4 watts 4 J8168A J8169A 406 watts available to ports 1-24 (provided by the internal source). 408/2044 watts available to ports 25-48 (provided by the EPS source).
Introduction Quick Reference Table Model/ Device 2915-8G-PoE Port Type Port Count/ PoE watts per port1 Gig Uplink Ports 10/100/1000 4 @ 15.4 watts 8 @ 7.5 watts 22 J9562A 42 J8696A 42 J8696A 42 J8696A 48 24 @ 15.4 watts 48 @ 7.5 watts 42 J8696A 786 watts available to ports 148 (provided by both the internal and external sources). 24 24 @ 15.4 watts 24 @ 30 watts 42 J9310A 10/100/1000 786 watts available to ports 124 (provided by both the internal and external sources).
Introduction Quick Reference Table Model/ Device Port Type E3800-24G-PoE+-2SFP+ 10/100/1000 E3800-24G-PoE+-2XG E3800-48G-PoE+-4SFP+ 10/100/1000 E3800-48G-PoE+-4XG Port Count/ PoE watts per port1 Gig Uplink Ports RPS/EPS Maximum Power Internal and External 24 Depends on how many power supplies and on what voltage the power supply is connected to, either 110 or 220 voltage 2 None Up to 1080 watts of PoE/PoE+ power across all RJ-45 ports depending on the voltage the power supply is connected to, e
Introduction Quick Reference Table Model/ Device Port Type Port Count/ PoE watts per port1 Gig Uplink Ports RPS/EPS Maximum Power Internal and External E8206zl 10/100/1000 Depends on Depends on which modules which modules and how many and how many modules. modules. Range of 4-24 Range of 24-144 J9306A A maximum of 2 internal power supplies up to 1800 watts and the external source can provide up to 1800 watts.
Introduction Quick Reference Table Model/ Device Port Type Port Count/ PoE watts per port1 Gig Uplink Ports zl PoE+ 24-Port Module (J9307A) 10/100/1000 24 up to 30 watts@ 200240v 0 J9306A Depends on voltage (100-127 or 200-240) and if using PoE or PoE+ zl PoE+ 20-Port Module (J9308A) 10/100/1000 20 up to 30 watts@ 200240v 0-4 J9306A Depends on voltage (100-127 or 200-240) and if using PoE or PoE+ 10/100 24 up to 30 watts@ 200240v 0 J9306A Depends on voltage (100-127 or 200-240) and if u
Introduction Quick Reference Table Model/ Device 1 Port Type Port Count/ PoE watts per port1 Gig Uplink Ports RPS/EPS Maximum Power Internal and External Redundant power and extra PoE power can be added by connecting a Redundant and external power supply. 2 The uplink ports on this switch are dual-personality. If the RJ-45 port is used the mini-GBIC port is disabled. 3 The PoE power for this module must come from an external power supply, it does not have any internal PoE power.
2 Operating Rules This chapter discusses the operating rules and characteristics of the HP ProCurve product capabilities, switches and external power supplies.
Operating Rules Overview of Switch PoE Operation Overview of Switch PoE Operation ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ 2-2 The Switch 2520-8-PoE provisions (allocates power to) ports 1-8 with 67 watts of power for PoE applications compatible with the IEEE 802.3af standard. The Switch 2520-24-PoE provisions ports 1-24 with 195 watts of power for PoE applications compatible with the IEEE 802.3af standard.
Operating Rules Overview of Switch PoE Operation ■ ■ ■ ■ Note The Switch 3500yl-24G-PoE+ can supply up to 398 watts of PoE power across the 24 ports. The Switch 3500yl-48G-PoE+ can supply up to 398 watts of PoE power across the 48 ports for PoE+ applications compatible with the IEEE 802.3at standard.
Operating Rules Configuring PoE/PoE+ Power Using the CLI Configuring PoE/PoE+ Power Using the CLI Allocating PoE Power by Class or User-defined Power Level The 2910al, 3500, 3500yl, E3800 and the E5400zl/E8200zl switches provide maximum flexibility by allowing the switch to detect and display 802.3af or 802.3at device class, but does not enforce the power level specified in each device class.
Operating Rules Configuring PoE/PoE+ Power Using the CLI Switch Priority Class Using a priority class method, a power priority of Low (the default), High, or Critical is assigned to each enabled PoE port. This assignment is done through the command line interface of the switch and alters the hardware port-number priority for power allocation. ■ Low (default) - This priority class receives power only if all other priority classes are receiving power.
Operating Rules PoE Power Characteristics For example if the threshold is set at 50%, the switch informs you that the switch has exceeded the threshold when 51% of available PoE power is being used. For more information, see the Management and Configuration Guide for your switch at: www.hp.
Operating Rules PoE Power Characteristics As you can see in the table for classifications 0-3, any 802.3af compliant PD will never require more than 12.95 watts. The switch provides a minimum of 15.4 watts at the port in order to guarantee enough power to run a device, after accounting for line loss. For classification 4, the switch provides 30 watts at the port in order to guarantee enough power to run a device, after accounting for line loss.
Operating Rules Provisioning Power for PoE Provisioning Power for PoE All of these PoE switches support an external power supply that can provide either redundant or extra PoE power. It is important to understand how PoE power is provisioned in order to use these external power supplies efficiently. The following chapters will discuss this in detail.
Operating Rules Provisioning Power for PoE Table 2-2. Maximum Power Allocations PoE Devices Internal Only PoE for Switches 2520-8-PoE and 2520G-8-PoE 67 watts available to ports 1-8. PoE for Switch 2520-24-PoE and 2520G-24-PoE 195 watts available to ports 1-24.
Operating Rules Provisioning Power for PoE Table 2-3. Maximum Power Allocations PoE Devices Internal Only Internal and EPS EPS Only PoE for Switch 2600-8-PWR 126 watts available to ports 1-8. 126 watts available to ports 1-8 (provided by the internal source). 408/204* watts available, provided by the EPS source. The internal power supply has failed, and the EPS provides 408/204* watts to ports 1-8. PoE for Switch 2626-PWR 406 watts available to ports 1-24.
Operating Rules Provisioning Power for PoE The Switch 2626-PWR has 24 ports and its internal PoE power supply provides 406 watts across all 24 ports. If a 600 RPS/EPS or a 610 EPS device is connected to the Switch 2626-PWR for the purpose of supplying external power to the PoE portion of the switch, there will be either 408 watts or 204 watts of power available should the switch’s internal PoE power supply fail.
Operating Rules Provisioning Power for PoE Table 2-4. Maximum Power Allocations PoE Devices Internal Only Internal and EPS EPS Only PoE for Switch 2610-24/12PWR 126 watts available to ports 1-12 126 watts available to ports 1-12 (provided by the internal source). 408/ 204* watts available, provided by the EPS source. The internal power supply has failed, and the EPS provides 408/204* watts to ports 1-12. PoE for Switch 2610-24-PWR 406 watts available to ports 1-24.
Operating Rules Provisioning Power for PoE single switch is connected to the EPS ports on the 600 RPS/EPS or a single port of a pair on the 610 EPS, 408 watts are available, providing fully redundant PoE power to the switch. If two switch devices are connected to the EPS ports on the 600 RPS/EPS or to both ports of a pair on the 610 EPS, only 204 watts are provided to the switch if the internal PoE power supply fails. The Switch 2610-48-PWR PoE power requirements are different.
Operating Rules Provisioning Power for PoE Since there is no external power supply available for this switch, PoE power is limited to 67 watts provisioned across all 8 ports. Therefore, proper provisioning is very important. HP E2620-PoE+ Switches Maximum PoE+ Power The Switch E2620-24-PPoE+ provisions (allocates power to) ports 1-12 with 126 watts of power for PoE and PoE+ applications compatible with the IEEE 802.3af and the 802.3at standard and some pre-standard devices.
Operating Rules Provisioning Power for PoE PoE/PoE+ Allocation Using LLDP Information A PoE port can automatically configure certain PoE+ link partner devices if the device supports advertising of its PoE needs. By enabling PoE LLDP detection, available information about the power requirements of the PD may be used by the switch to configure the power allocation. The initial configuration for PoE ports may change if more accurate configuration information is provided by way of LLDP.
Operating Rules Provisioning Power for PoE PoE Power Requirements The Switch 2910al-24G-PoE+ has 24 ports with an internal PoE power supply that provides 382 watts of power across all 24 ports. The Switch 2910al-48GPoE+ has 48 ports with 382 watts of power across all 48 ports. The HP ProCurve 630 RPS/EPS can provide an extra 388 watts for a total of 770 watts.
Operating Rules Provisioning Power for PoE Since there is no external power supply available for this switch, PoE power is limited to 67 watts provisioned across all 8 ports. Therefore, proper provisioning is very important. HP ProCurve 3500-PoE Switches Maximum PoE Power The HP ProCurve 3500-24-PoE switch provisions (allocates power to) ports 1-24 with 398 watts of power for PoE applications compatible with the IEEE 802.3af standard and some pre-standard devices.
Operating Rules Provisioning Power for PoE 25-48, so that neither set of ports receives the entire 398 watts. This is designed for the integrity and safety of PoE during power balancing to properly detect PDs and bring them online. PoE Allocation Using LLDP Information You can have the port automatically configure certain PoE link partner devices if the devices supports advertising of its PoE needs.
Operating Rules Provisioning Power for PoE PoE Power Requirements The Switch 3500yl-24G-PWR has 24 ports with an internal PoE power supply that provides 398 watts of 50V power across all 24 ports. The Switch 3500yl48G-PWR has 48 ports with 398 watts of 50V power across all 48 ports. There is a special power provision on the Switch 3500yl-48G-PWR, Where the switch reserves 22 watts for each bank of 24 ports, ports 1-24 and 25-48, so that neither set of ports receives the entire 398 watts.
Operating Rules Provisioning Power for PoE Table 2-11. Maximum Power Allocations for the 3500yl-PoE+ Switches PoE Devices Internal Only PoE for Switch 3500yl-24G-PoE+ 398 watts available to ports 1-24. PoE for Switch 3500yl-48G-PoE+ 398 watts available to ports 1-48. Internal and External External Only 786 watts available to ports 1-24 The internal power supply has failed, 388 watts available to ports (provided by the internal and external source). 388 watts available 1-24 from the external source.
Operating Rules Provisioning Power for PoE Table 2-12. Maximum Power Allocations for the E3800 PoE+ Switches PoE Devices One power supply Two power supplies PoE for the 573 watts available to ports 1-24 with 127 W 1080 watts available to ports 1-24 with 127 W being used from the first power supply by the being used by the system at 110 volts. E3800-24G-PoE+-2SFP+ system at 110 volts.
Operating Rules Provisioning Power for PoE HP ProCurve E5400zl/E8200zl Switches Maximum PoE Power Each chassis provisions (allocates power to) ports 1-24 of each module with the watts associated with the specific power supply installed. The power for PoE applications is compatible with the IEEE 802.3af standard and some prestandard devices. As soon as a module is installed into the switch, 22 watts is reserved for its use.
Operating Rules Provisioning Power for PoE Table 2-15.
Operating Rules Provisioning Power for PoE ■ ■ HP ProCurve Switch zl 24-Port 10/100/1000 PoE Module (J8702A) HP ProCurve Switch zl 20-Port 10/100/1000 + 4-port Mini-GBIC Module (J8705A) Each group of 24 ports is its own management group and needs to have a minimum allocation associated with it in order to properly detect PDs and bring them online. Each group of 24 ports will have a PoE power allocation of at least 22 watts.
Operating Rules Provisioning Power for PoE HP ProCurve Switch xl PoE Module for the 5300xl Switch For the HP ProCurve Switch xl PoE Module to function it must be installed in an HP ProCurve Switch 5300xl. The module will receive it’s operational power from the switch and its PoE power from the 600 RPS/EPS or an 610 EPS. Table 2-16. Maximum Power Allocations PoE Devices Internal Only Internal and EPS EPS Only HP ProCurve Switch xl PoE Module No internal PoE power. No internal PoE power. (See EPS only.
Operating Rules Provisioning Power for PoE 2-26
3 Planning and Implementation for the 2520 and 2520G Switches This chapter discusses the planning process a user should follow to successfully implement PoE using a 2520 or 2520G Switch. After understanding what PoE is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning the PoE Configuration This section assists you in building a PoE configuration.
Planning and Implementation for the 2520 and 2520G Switches Planning the PoE Configuration HP ProCurve 2520-8-PoE and 2520G-8-PoE Configurations The table in the example configuration contain entries that show the PoE power available when the 2520-8-PoE or 2520G-8-PoE is used to supply PoE power. 8 ports can receive up to 8 watts of PoE power 8 ports can receive up to 7.5 watts of PoE power Figure 3-1.
Planning and Implementation for the 2520 and 2520G Switches Planning the PoE Configuration HP ProCurve 2520-24-PoE and 2520G-24-PoE Configurations The table in the example configuration contain entries that show the PoE power available when the 2520-24-PoE or 2520G-24-PoE is used to supply PoE power. ProCurve Switch 2520-24-PoE ProCurve Switch 2520G-24-PoE 12 ports can receive up to 15.4 watts of PoE power 24 ports can receive up to 7.5 watts of PoE power 12 ports can receive up to 15.
4 Planning and Implementation for the 2600-PWR Switches This chapter discusses the planning process a user should follow to successfully implement PoE using a 2600-PWR Switches. After understanding what PoE is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning the PoE Configuration This section assists you in building a PoE configuration.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration The maximum power figure must be less than the maximum power available when the switch is powered by the 600 RPS/EPS or the 610 EPS unit, taking into consideration the number of switches the 600 RPS/EPS or 610 EPS unit is powering. Note Full redundancy is achieved by connecting both the RPS and EPS ports of the 2600-PWR Switches to the corresponding ports of a 600 RPS/EPS.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration Source of Power Internal PoE Power Supply Internal plus External PoE Power Supply External PoE Power Supply (Failed Internal PoE Power Supply) ■ ■ Watts Available # of Ports Powered and Average watts/Port Redundant # of Ports Powered and Average watts/ Port 126 8 @ average 15.4 W each None 126 + 408 8 @ average 15.4 W each 8 @ average 15.4 W each 8 @ average 15.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration Source of Power Internal PoE Power Supply Internal plus External PoE Power Supply External PoE Power Supply (Failed Internal PoE Power Supply) Watts Available # of Ports Powered and Average watts/Port Redundant # of Ports Powered and Average watts/ Port 406 24 @ average 15.4 W each None 406 + 408 24 @ average 15.4 W each 24 @ average 15.4 W each 24 @ average 15.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration Source of Power Watts Available # of Ports Powered and Average watts/Port Redundant # of Ports Powered and Average watts/ Port Internal PoE Power Supply 406 24 @ average 15.4 W each None Internal plus External PoE Power Supply 406 + 204 24 @ average 15.4 W each 24 @ 7.5 W each 12 @ 15.4 W each 1 - 24 External PoE 204 Power Supply (Failed Internal PoE Power Supply) ■ 24 @ 7.5 W each 12 @ 15.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration ProCurve 2650-PWR Configurations The tables in the example configurations contain entries that show the PoE power available when the 2650-PWR is used alone. When used with the 600 RPS/EPS or 610 EPS unit, additional PoE power is available to the PoE ports and PoE power is available should the switch’s internal PoE power supply fail.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration 600 RPS/EPS ProCurve Switch 2650-PWR Figure 4-4. Example of an 600 RPS/EPS Power One Switch Source of Power Internal PoE Power Supply Watts Available 406 24 @ average 15.4 W each Redundant # of Ports Powered and Average watts/ Port None 48 @ average 7.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration 600 RPS/EPS ProCurve Switch 2650-PWR Figure 4-5. Example of an 600 RPS/EPS Powering Two Switches Source of Power Internal PoE Power Supply Watts Available 406 # of Ports Powered and Average watts/Port 24 @ average 15.4 W each Redundant # of Ports Powered and Average watts/ Port None 48 @ average 7.5 W each Internal plus 406 + 204 External PoE 1 - 24 25 - 48 Power Supply 24 @ average 15.4 W each and 24 @ 7.
Planning and Implementation for the 2600-PWR Switches Planning the PoE Configuration ProCurve Switch 2650-PWR 50 V 16 A 50 V 16 A 50 V 16 A 50 V 16 A 12 V RPS 7.5 A 12 V RPS 7.5 A 12 V RPS 7.5 A 12 V RPS 7.5 A hp procurve 600 RPS/EPS Line: 50/60 Hz. 100-240 V~ 7.5 A Line: 50/60 Hz. 100-240 V~ 7.5 A Line: 50/60 Hz. 100-240 V~ 7.5 A Line: 50/60 Hz. 100-240 V~ 7.
5 Planning and Implementation for the 2610-PWR Switches This chapter discusses the planning process a user should follow to successfully implement a PoE 2610-PWR Switches. The 2610-PWR switches and the 2600-PWR switches utilize a common PoE implementation. Port counts, power supply wattages, specifications, and functionality for these two platforms are the same with respect to PoE. After understanding what PoE is and its operating rules, the next step to implementation is planning.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration Once you have selected your specific configuration and the PoE power provided, you then add up the maximum amount of power each of your IEEE 802.3af-compliant devices require (use maximum power in watts, usually found on a product’s data sheet). Adjust this total maximum power figure by adding 16% to account for possible line loss.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration 600 RPS/EPS ProCurve Switch 2610-24/12PWR Figure 5-1. Example of a 600 RPS/EPS Powering One 2610-24/12PWR Switch Source of Power Watts Available Internal PoE Power Supply 126 12 @ average 7.5 W each 8 @ average 15.4 W each None 126 + 408 12 @ average 15.4 W each 12 @ average 7.5 W each 12 @ average 15.4 W each 12 @ average 7.5 W each 12 @ average 15.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration ProCurve 2610-24-PWR Configurations The tables in the example configurations contain entries that show the PoE power available when the 2610-24-PWR is used alone. When used with the 600 RPS/EPS or 610 EPS unit, PoE power is available to the PoE ports should the internal PoE power supply fail. Table entries show the PoE power available when the 600 RPS/EPS or 610 EPS alone provides PoE power.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration 600 RPS/EPS ProCurve Switch 2610-24-PWR Figure 5-3. Example of an 600 RPS/EPS Powering Two 2610-24-PWR Switches Source of Power Internal PoE Power Supply Internal plus External PoE Power Supply External PoE Power Supply (Failed Internal PoE Power Supply) ■ Watts Available # of Ports Powered and Average watts/Port Redundant # of Ports Powered and Average watts/ Port 406 24 @ average 15.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration ProCurve 2610-48-PWR Configurations The tables in the example configurations contain entries that show the PoE power available when the 2610-48-PWR is used alone. When used with the 600 RPS/EPS or 610 EPS unit, additional PoE power is available to the PoE ports and PoE power is available should the switch’s internal PoE power supply fail.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration 600 RPS/EPS ProCurve Switch 2610-48-PWR Figure 5-4. Example of an 600 RPS/EPS Powering One 2610-48-PWR Switch Source of Power Internal PoE Power Supply Watts Available 406 24 @ average 15.4 W each Redundant # of Ports Powered and Average watts/ Port None 48 @ average 7.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration 600 RPS/EPS ProCurve Switch 2610-48-PWR Figure 5-5. Example of an 600 RPS/EPS Powering Two 2610-48-PWR Switches Source of Power Internal PoE Power Supply Watts Available 406 # of Ports Powered and Average watts/Port 24 @ average 15.4 W each Redundant # of Ports Powered and Average watts/ Port None 48 @ average 7.5 W each Internal plus 406 + 204 External PoE 1 - 24 25 - 48 Power Supply 24 @ average 15.
Planning and Implementation for the 2610-PWR Switches Planning Your PoE Configuration ProCurve Switch 2610-48-PWR 600 RPS/EPS Figure 5-6. Example of an 610 EPS Powering Four 2610-48-PWR Switches Source of Power Internal PoE Power Supply Watts Available 406 # of Ports Powered and Average watts/Port 24 @ average 15.4 W each Redundant # of Ports Powered and Average watts/ Port None 48 @ average 7.5 W each Internal plus External PoE Power Supply 406 + 204 1 - 24 25 - 48 24 @ average 15.
6 Planning and Implementation for the 2615 and 2915G Switches This chapter discusses the planning process a user should follow to successfully implement PoE using a 2615 or 2915G Switch. After understanding what PoE is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning the PoE Configuration This section assists you in building a PoE configuration.
Planning and Implementation for the 2615 and 2915G Switches Planning the PoE Configuration HP ProCurve 2615-8-PoE and 2915-8G-PoE Configurations The table in the example configuration contain entries that show the PoE power available when the 2615-8-PoE or 2915-8G-PoE is used to supply PoE power. 8 ports can receive up to 7.5 watts of PoE power 8 ports can receive up to 7.5 watts of PoE power Figure 6-1.
7 Planning and Implementation for the E2620 PoE+ Switches This chapter discusses the planning process a user should follow to successfully implement PoE+ using an E2620 Switch. After understanding what PoE+ is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning Your PoE Configuration This section assists you in building a PoE+ configuration.
Planning and Implementation for the E2620 PoE+ Switches Planning Your PoE Configuration HP E2620-24-PPoE+ Configurations The table in this example configuration contains entries that show the PoE+ power available for the E2620-24-PPoE+. 4 ports can receive up to 30 watts of PoE+ power Figure 7-1.
Planning and Implementation for the E2620 PoE+ Switches Planning Your PoE Configuration HP E2620-24-PoE+ Configurations The table in this example configuration contains entries that show the PoE+ power available for the E2620-24-PoE+. 12 ports can receive up to 30 watts of PoE+ power or 24 ports can receive up to 15.4 watts of PoE power Figure 7-2.
Planning and Implementation for the E2620 PoE+ Switches Planning Your PoE Configuration One E2620-24-PoE+ switch can be supported by one 630 RPS/EPS. This is a full redundant configuration. The switch can be supplied with power should the internal power supply fails. The 630 RPS/EPS can supply system power to keep the switch powered on and PoE+ power to supply the attached PoE+ devices with power.
Planning and Implementation for the E2620 PoE+ Switches Planning Your PoE Configuration 12 ports can receive up to 30 watts of PoE+ power or All 24 ports can receive up to 15.4 watts of PoE power or 48 ports can receive up to 7.5 watts of PoE power Figure 7-4. Example of a E2620-48-PoE+ Switch Source of Power Watts Available Internal PoE+ Power Supply 364 # of Ports Powered and Average watts/Port 12 @ average 30 W each 24 @ average 15.4 W each 48 @ average 7.5 W each 48 @ average 4.
Planning and Implementation for the E2620 PoE+ Switches Planning Your PoE Configuration Source of Power Watts Available # of Ports Powered and Average watts/Port Internal PoE+ Power Supply 364 Internal plus External PoE+ power Supply 364 + 3881 24 @ average 30.0 W each for a total of 720 48 @ average 15.4 W each 48 @ average 7.5 W each 48 @ average 4.0 W each 12 @ average 30.0 W each for a total of 360 W 23 @ average 15.4 W each 48 @ average 7.5 W each 48 @ average 4.
8 Planning and Implementation for the Switch xl PoE module This chapter discusses the planning process a user should follow to successfully implement PoE using a Series 5300xl PoE module. After understanding what PoE is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning Your PoE Configuration This section assists you in building a reliable PoE configuration.
Planning and Implementation for the Switch xl PoE module Planning Your PoE Configuration ProCurve Switch PoE xl Module Configurations with a 600 RPS/EPS For the ProCurve Switch xl PoE Module to function it must be installed in an ProCurve Switch 5300xl. The module will receive it’s operational power from the switch and it’s PoE power from the 600 RPS/EPS or an 610 EPS.
Planning and Implementation for the Switch xl PoE module Planning Your PoE Configuration ProCurve Switch 5300xl Std ProCurve Switch xl PoE modules Link 1 Mode 2 LED Mode 3 PoE PoE 4 PoE-Ready 10/100-TX Ports (1-24) all ports are HP Auto-MDIX EPS Status 5 6 13 14 15 16 17 Link Std Link 18 Mode hp procurve PoE xl module J8161A LED Mode PoE PoE 1 Mode 2 3 4 7 8 9 10 PoE-Ready 10/100-TX Ports (1-24) all ports are HP Auto-MDIX EPS Status 5 6 13 14 15 16 17 20 21
Planning and Implementation for the Switch xl PoE module Planning Your PoE Configuration ProCurve Switch PoE xl Module Configurations with a 610 EPS ProCurve Switch 5300xl Std Link ProCurve Switch xl PoE modules 1 Mode 2 LED Mode 3 PoE PoE 4 PoE-Ready 10/100-TX Ports (1-24) all ports are HP Auto-MDIX EPS Status 5 6 13 14 15 16 17 Link Std Link 18 Mode hp procurve PoE xl module J8161A LED Mode PoE PoE 1 Mode 2 3 4 7 8 9 10 PoE-Ready 10/100-TX Ports (1-24) all ports are
Planning and Implementation for the Switch xl PoE module Planning Your PoE Configuration ProCurve Switch 5300xl Std ProCurve Switch xl PoE modules Link 1 Mode 2 LED Mode 3 PoE PoE 4 PoE-Ready 10/100-TX Ports (1-24) all ports are HP Auto-MDIX EPS Status 5 6 13 14 15 16 17 Link Std Link 18 Mode hp procurve PoE xl module J8161A LED Mode PoE PoE 1 Mode 2 3 4 7 8 9 10 PoE-Ready 10/100-TX Ports (1-24) all ports are HP Auto-MDIX EPS Status 5 6 13 14 15 16 17 20 21
Planning and Implementation for the Switch xl PoE module Planning Your PoE Configuration ProCurve Switch 5300xl Std Link 1 Mode 2 LED Mode PoE PoE PoE-Ready 10/100-TX Ports (1-24) all ports are HP Auto-MDIX EPS Status 4 3 5 6 13 14 15 16 17 Link Std Link 18 Mode ProCurve Switch xl PoE modules hp procurve PoE xl module xl J8161A 7 8 10 9 Std Link LED Mode 11 PoE PoE 1 Mode 2 3 4 7 8 9 10 12 20 19 2 LED Mode PoE PoE PoE-Ready 10/100-TX Ports (1-24) all po
9 Planning and Implementation for the 2910al PoE+ Switches This chapter discusses the planning process a user should follow to successfully implement PoE+ using a Series 2910al Switch. After understanding what PoE+ is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning Your PoE Configuration This section assists you in building a PoE+ configuration.
Planning and Implementation for the 2910al PoE+ Switches Planning Your PoE Configuration ProCurve 2910al-24G-PoE+ Configuration ProCurve Switch Mdl EPS RPS Fault Locator J9146A Status PoE LED Tmp Mode Fan Act FDx Spd * * Spd mode: Link 1 Mode 3 5 7 9 11 Link 13 Mode 15 17 19 21T 23T Link 21S Mode 23S Link 2 Mode 4 6 8 10 12 Link 14 Mode 16 18 20 22T 24T Link 22S Mode 24S off = 10 Mbps 2 flash = 100 Mbps on = 1 Gbps 3 flash = 10 Gbps PoE Test Console PoE+
Planning and Implementation for the 2910al PoE+ Switches Planning Your PoE Configuration The table in this example configuration contains entries that show the PoE+ power available for the 2910al-24G-PoE+ when connecting to an external power supply. 2910al 24 port switch 630 RPS/EPS Figure 9-2. Example of a 2910al-24G-PoE+ Switch connecting to a 630 RPS/EPS The same considerations apply for the mini-GBIC ports as in the previous example. One 2910al-24G-PoE switch can be supported by one 630 RPS/EPS.
Planning and Implementation for the 2910al PoE+ Switches Planning Your PoE Configuration ProCurve 2910al-48G-PoE+ Configuration PoE+ power requirements are figured differently for the 2910al-48G-PoE+ switch, see PoE+ Power on page 2-15. The table in this example configuration contains entries that show the PoE+ power available for the 2910al-48G-PoE+ switch.
Planning and Implementation for the 2910al PoE+ Switches Planning Your PoE Configuration The table in this example configuration contains entries that show the PoE+ power available for the 2910al-48G-PoE+ when connecting to an external power supply. 2910al 48 port switches 630 RPS/EPS Figure 9-4.
10 Planning and Implementation for the 3500 Switches This chapter discusses the planning process to follow to successfully implement PoE on a 3500 switch. After understanding PoE and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning Your PoE Configuration This section assists you in building a PoE configuration.
Planning and Implementation for the 3500 Switches Planning Your PoE Configuration HP ProCurve 3500-24-PoE Switch Configuration The table in this example configuration shows the PoE power available for the HP ProCurve 3500-24-PoE switch using the internal power supply. All 24 ports can receive up to 15.4 watts of PoE power Figure 10-1.
Planning and Implementation for the 3500 Switches Planning Your PoE Configuration The table in this example configuration shows the PoE power available for the HP ProCurve 3500-24-PoE switch when configured with an external power supply. 3500- 24 port switches 620 RPS/EPS Figure 10-2. Example of two HP ProCurve 3500-24-PoE Switches connecting to an HP ProCurve 620 External and Redundant Power Supply (J8696A) The same considerations apply for the mini-GBIC ports as in the previous example.
Planning and Implementation for the 3500 Switches Planning Your PoE Configuration HP ProCurve 3500-48-PoE Switch Configuration PoE power requirements are determined differently for the HP ProCurve 350048-PoE switch. In the default configuration PoE power priority is determined by port number, with the lowest numbered port (port 1) having the highest priority, and the highest numbered port (port 48) having the lowest priority.
Planning and Implementation for the 3500 Switches Planning Your PoE Configuration It takes 369.6 watts to fully provision 24 ports (plus 5 watts to account for load fluctuations), leaving 1.4 watts to be returned to the pool of available watts. This can then be added to the 22 watts held in reserve for the bank of ports 25-48, giving a total of available watts of 23.4 watts.
Planning and Implementation for the 3500 Switches Planning Your PoE Configuration The table in this example configuration shows the PoE power available for the HP ProCurve 3500-48-PoE switch. 3500- 48 port switches 620 RPS/EPS Figure 10-4.
11 Planning and Implementation for the 3500yl Switches This chapter discusses the planning process a user should follow to successfully implement PoE and PoE+ using a 3500yl switch. After understanding what PoE is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Planning Your PoE or PoE+ Configuration This section assists you in building a PoE or PoE+ configuration.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration Each example shows a complete configuration. A table shows the PoE or PoE+ power available to connected PoE or PoE+ devices when using just the switch or when connecting to an external power supply.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration The table in this example configuration contains entries that show the PoE power available for the 3500yl-24G-PWR when connected to an external power supply. 3500yl 24 port switches 620 RPS/EPS Figure 11-2. Example of two 3500yl-24G-PWR Switches connecting to a HP ProCurve 620 External and Redundant Power Supply (J8696A) The same considerations apply for the mini-GBIC ports as in the previous example.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration HP ProCurve 3500yl-48G-PWR Configuration PoE power requirements are figured differently for the 3500yl-48G-PWR switch. In the default configuration PoE power priority is determined by port number, with the lowest numbered port (port 1) having the highest priority, and the highest numbered port (port 48) having the lowest priority.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration It takes 369.6 watts to fully provision 24 ports (plus 5 watts to account for load fluctuations), leaving 1.4 watts to be returned to the pool of available watts. This can then be added to the 22 watts held in reserve for the bank of ports 25-48, giving a total of available watts of 23.4 watts.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration The table in this example configuration contains entries that show the PoE power available for the 3500yl-48G-PWR. 3500yl 48 port switches 620 RPS/EPS Figure 11-4.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration HP ProCurve 3500yl-24G-PoE+ Configuration The table in this example configuration contains entries that show the PoE+ power available for the 3500yl-24G-PoE+. 13 ports can receive up to 30 watts of PoE+ power All 24 ports can receive up to 15.4 watts of PoE power Figure 11-5.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration The table in this example configuration contains entries that show the PoE+ power available for the 3500yl-24G-PoE+. 3500yl 24 port switch 630 RPS/EPS Figure 11-6. Example of a 3500yl-24G-PoE+ Switch connecting to a HP ProCurve 630 External and/or Redundant Power Supply (J9443A) The same considerations apply for the mini-GBIC ports as in the previous example.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration HP ProCurve 3500yl-48G-PoE+ Configuration PoE+ power requirements are figured differently for the 3500yl-48G-PoE+ switch. In the default configuration PoE+ power priority is determined by port number, with the lowest numbered port (port 1) having the highest priority, and the highest numbered port (port 48) having the lowest priority.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration It takes 330 watts to fully provision 11 ports (plus 5 watts to account for load fluctuations), leaving 19 watts to be returned to the pool of available watts. This can then be added to the 22 watts held in reserve for the bank of ports 25-48, giving a total of available watts of 41 watts. Since a port requires 33 watts to power up a PoE+ device, there is not enough available power to power another device.
Planning and Implementation for the 3500yl Switches Planning Your PoE or PoE+ Configuration The table in this example configuration contains entries that show the PoE+ power available for the 3500yl-48G-PoE+. 3500yl 24 port switch 630 RPS/EPS Figure 11-8.
12 Planning and Implementation for the E3800 Switches This chapter discusses the planning process a user should follow to successfully implement PoE and PoE+ using a E3800 Switch. After understanding what PoE is and its operating rules, the next step to implementation is planning. See “General Considerations” page A-1, for an example list of considerations during the planning phase. Note In the stacked environment, the PoE/PoE+ will still be managed at the member level.
Planning and Implementation for the E3800 Switches Planning Your PoE or PoE+ Configuration ■ ■ HP E3800-48G-PoE+-4SFP+ Switch, or HP E3800-48G-PoE+-4XG Switch, with one power supply HP E3800-48G-PoE+-4SFP+ Switch, or HP E3800-48G-PoE+-4XG Switch, with two power supplies Each example shows a complete configuration. A table shows the PoE or PoE+ power available to connected PoE or PoE+ devices when using one or two power supplies in the switch.
Planning and Implementation for the E3800 Switches Planning Your PoE or PoE+ Configuration All these calculations assume worst-case device power and 100M cables and are the most conservative estimate of what can be supported. Actual power usage and number of devices supported will be different in each case.
Planning and Implementation for the E3800 Switches Planning Your PoE or PoE+ Configuration The table in this example configuration contains entries that show the PoE power available for the E3800-24G-PoE+-2SFP+ or E3800-24G-PoE+-2XG Switch when two power supplies are installed. All 24 ports can supply up to 30 watts of PoE+ power or 15.4 watts of PoE power Figure 12-2.
Planning and Implementation for the E3800 Switches Planning Your PoE or PoE+ Configuration HP E3800-48G-PoE+-4SFP+ or HP E3800-48G-PoE+4XG Switch Configurations The table in this example configuration contains entries that show the PoE/ PoE+ power available for the E3800-48G-PoE+-4SFP+ or E3800-48G-PoE+4XG Switch when using only one power supply. PoE power requirements are figured differently for the E3800-48G-PoE+4SFP+ or E3800-48G-PoE+-4XG Switch.
Planning and Implementation for the E3800 Switches Planning Your PoE or PoE+ Configuration Source of Power Watts Available One 1000 watt 185 W for Power Supply system use, and 815 W for PoE+ @ 220 V # of Ports Powered and Average watts/Port Redundant # of Ports Powered and Average watts/ Port 27 @ average 30 W each for None a total of 720 W 48 @ average 15.4 W each 48 @ average 7.5 W each The lowest loaded bank of ports (1-24 or 25-48) has 22 watts reserved.
Planning and Implementation for the E3800 Switches Planning Your PoE or PoE+ Configuration By load balancing in this manner there could be a specified number of devices on one bank of ports, say 1-24, and another specified number of devices on the other bank of ports, 25-48 powered at an average of 30 watts each. Both of these examples use maximum device wattage. If however, devices using lower wattages are connected there could be more devices connected to the switch than shown in these examples.
Planning and Implementation for the E3800 Switches Planning Your PoE or PoE+ Configuration Source of Power 12-8 Watts Available # of Ports Powered and Average watts/Port Redundant # of Ports Powered and Average watts/Port Two 1000 185 W for system watt Power use, and 515 W+ Supplies 700 W (for a max of 1080 W) @ 110 V 36 @ average 30 W each for a total of 1080. 48 @ average 15.4 W each 48 @ average 7.5 W each 17 @ average 30 W each for a total of 570 W 33 @ average 15.4 W each 48 @ average 7.
13 Planning and Implementation for the E5400zl/ E8200zl Switches This chapter discusses the planning process a user should follow to successfully implement PoE or PoE+ on E5400zl/E8200zl switches. The E5412zl chassis and the E8212zl chassis share a common PoE/PoE+ implementation, and the E5406zl chassis and the E8206zl chassis share a common PoE/PoE+ implementation. Port counts, power supply wattages, specifications, and functionality for these two platforms are the same with respect to PoE and PoE+.
Planning and Implementation for the E5400zl/E8200zl Switches Planning Your PoE Configuration Planning Your PoE Configuration This section assists you in building a reliable and, if required, redundant PoE configuration. Using the following examples you can plan, build, and connect your PoE devices quickly and easily. Your configuration may vary, however, this section discusses some of the more common configurations.
Planning and Implementation for the E5400zl/E8200zl Switches Planning Your PoE Configuration Table 13-1. E5406zl/E8206zl System Power Configurations Number of Power Supplies Redundancy Model J8712A (110 or 220 V) J8713A (220 V only) N + 1 or Full Redundant System Power 1 0 - None 2 0 Full up to 600 W system power 0 1 - None 0 2 Full Up to 600 W system power System Power(12v) Table 13-2.
Planning and Implementation for the E5400zl/E8200zl Switches Planning Your PoE Configuration Switch Model E5406zl/ E8206zl Number of Power Supplies J8712A J8713A (110 or 220 volts) (220 volts only) Redundancy Model Non-Redundant Power Available N+1 or Full Redundant PoE Power Non-Redundant PoE Power Mixed PoE Power (NOT Recommended)) 1 1 N+1 System and Redundancy up to 273 W, see page 1313 1173 W (With External Power Supplies Added> 3 0 N+1 Up to 546 W 819 W 4 0 Full Up to 546 W 1092
Planning and Implementation for the E5400zl/E8200zl Switches Planning Your PoE Configuration Switch Model E5406zl/ E8206zl (With External Power Supplies Added> Number of Power Supplies J9306A Redundancy Model Non-Redundant Power Available @ 110 - 127 V @ 200-240 V N + 1 or Full Redundant PoE/PoE+ Power Non-Redundant PoE/PoE+ Power 3 0 N+1 Up to 600 W 900 W 4 0 Full Up to 600 W 1200 W 0 3 N+1 Up to 1800 W 2700 W 0 4 Full Up to 1800 W 3600 W Power Configuration for HP 5412zl/821
Planning and Implementation for the E5400zl/E8200zl Switches Planning Your PoE Configuration Table 13-6.
Planning and Implementation for the E5400zl/E8200zl Switches Planning Your PoE Configuration Switch Model 5412zl/ 8212zl Number of Power Supplies J8712A J8713A (110 or 220 volts) (220 volts only) (With External Power Supplies Added> Redundancy Model Non-Redundant Power Available N+1 or Full Redundant PoE Power Non-Redundant PoE Power 5 0 N+1 Up to 1092 W 1365 W 6 0 Full Up to 819 W 1638 W 0 5 N+1 Up to 3600 W 4500 W 0 6 Full Up to 2700 W 5400 W Power Configuration for HP 5412zl/
Planning and Implementation for the E5400zl/E8200zl Switches Planning Your PoE Configuration Table 13-8.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Configuration Examples In the following configuration examples, each example shows a complete configuration. A table shows the PoE power available to connected PoE devices when using just the switch and when connecting an external power supply.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples To achieve the 16 ports at 15.4 watts the PoE devices must be divided up and connected to two different modules. Remember, as soon as a module is installed into the switch, 22 watts are reserved for its use. In order to use those watts, devices must be connected to that module or PoE power must be disabled to all ports on that module.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples In this example the load must be balanced or split between two or three modules in order to effectively use all 546 watts. The number of devices and wattage must be split between the modules. This would also help limit the effects of a single module failure. If one module fails, only the devices on that module would lose power.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples 900 watts for PoE 900 watts for PoE Power Supply J8713A Front Figure 13-5. Example of a 5406zl with two power supplies, J8713A This configuration (Figure 13-5) is an example of two power supplies supplying 900 watts each for a maximum of 1800 watts to a fully loaded chassis of 144 ports. Therefore out of the total 144 available ports, 116 can be powered at 15.4 watts each.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples 900 watts for PoE 273 watts for PoE Power Supply J8712A Front Power Supply J8713A Figure 13-6. Example of a 5406zl with two power supplies (J8712A and J8713A) In this example (Figure 13-6) there is one J8712A and one J8713A power supply supplying 1173 watts for PoE usage. This configuration offers 136 ports of which all can be powered at 7.0 watts each, and offers eight ports for fiber optic gigabit connectivity.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples In a system with mixed power supplies, failover is calculated based on the largest power supply failing. If it turns out to be the smaller power supply that fails, some of the ports that were powered off during the power failure will come back on. For example, in figure 4-5 there are mixed power supplies offering 900 W+ 273 W for 1173 W total.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Example Configuration for HP ProCurve E5406zl With One PoE/PoE+ Power Supply In this example there is one J9306A power supply operating at 110-127 volts, providing 300 watts for PoE/PoE+ usage. 300 watts for PoE/ PoE+ Front Power Supply J9306A Back Figure 13-9.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Example Configuration for HP ProCurve E8206zl with One PoE/PoE+ Power Supply In this example there is one J9306A power supply operating at 200-240 volts, providing 900 watts for PoE/PoE+ usage. Figure 13-10.HP ProCurve E8206zl Switch Source of Power Watts Available # of Ports Powered and Average watts/ (200-240 V) Port Single Internal PoE+ Power Supply (J9306A) 900 W 30 @ average 30 W each 58 @ average 15.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Example Configuration for HP ProCurve E8206zl with Two PoE/PoE+ Power Supplies This configuration is an example of two PoE+ power supplies supplying 900 watts each for a maximum of 1800 watts to a fully loaded chassis of 144 ports.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples HP ProCurve 5412zl/8212zl Configurations The 5412zl chassis and the 8212zl chassis share a completely common PoE/ PoE+ implementation. Port counts, power supply wattages, specifications, and functionality for these two platforms are the same with respect to PoE.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples To achieve the 35 ports at 15.4 watts the PoE devices must be divided up and connected to two different modules. Remember, as soon as a module is installed into the switch, 22 watts is reserved for its use. In order to use those watts, devices must be connected to that module or PoE power must be disabled to all ports on that module.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples 273 watts for PoE 53 ports can receive up to 15.4 watts of PoE 5 ports must be used on this module 273 watts for PoE Front 273 watts for PoE Back Figure 13-12.Example of a 5412zl with three power supplies, J8712A In this example (Figure 13-12) there are three power supplies supplying 273 watts each for a maximum of 819 watts. To achieve the 53 ports at 15.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples 71 ports can receive up to 15.4 watts of PoE power 273 watts for PoE 273 watts for PoE 273 watts for PoE 273 watts for PoE Front Back Figure 13-13.Example of a 5412zl with four power supplies, J8712A In this example (Figure 13-13) there are four power supplies supplying 273 watts each for a maximum of 1092 watts. All three modules can be used or six and a half modules (145 ports) at 7.5 watts per port.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Standard J8713A Configurations 900 watts for PoE Front 900 watts for PoE Back Figure 13-14.Example of a 5412zl with two power supplies, J8713A This configuration (Figure 13-14) is an example of two power supplies supplying 900 watts each for a maximum of 1800 watts to a fully loaded chassis of 288 ports. Therefore out of the total 288 available ports, 116 can be powered at 15.4 watts each.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples 900 watts for PoE 900 watts for PoE Front 900 watts for PoE Back Figure 13-15.Example of a 5412zl with three power supplies, J8713A This configuration (Figure 13-15) is an example of three power supplies supplying 900 watts each for a maximum of 2700 watts to a fully loaded chassis of 288 ports. Therefore out of the total 288 available ports, 175 can be powered at 15.4 watts each.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples 900 watts for PoE 900 watts for PoE 900 watts for PoE 900 watts for PoE Back Front Figure 13-16.Example of a 5412zl with four power supplies, J8713A This configuration (Figure 13-16) is an example of four power supplies supplying 900 watts each for a maximum of 3600 watts to a fully loaded chassis of 288 ports. Therefore out of the total 288 available ports, 233 can be powered at 15.4 watts each.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Mixed J8712A and J8713A Configurations Note HP Procurve highly recommends that the two types of power supplies are not mixed in the same 5412zl or 8212zl chassis. Although mixing power supplies is not recommended, the following examples demonstrate the most common usages. Refer to page 13-13 for the discussion on failover in a mixed power supply environment.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples The J8713A is only be able to power 6 module slots should both of the J8712As fail. You may not be able to supply all ports with PoE power depending on which modules and which ports are configured to supply PoE power. 273 watts for PoE 900 watts for PoE 900 watts for PoE Back Front Figure 13-18.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples 273 watts for PoE 273 watts for PoE 900 watts for PoE 900 watts for PoE Back Front Figure 13-19.Example of a 5412zl with four power supplies (two J8712A and two J8713A) In this example (Figure 13-19) there are two J8712A and two J8713A power supplies supplying 2892 watts for PoE usage. With this configuration, 187 ports (or more than 7 modules) can be provisioned at 15.4 watts, or all 288 ports can be powered at 7.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Using the HP ProCurve 1500W PoE+ zl Power Supply (J9306A) The J9306A power supply provides PoE/PoE+ power for zl switches. The physical configurations are like those seen for the E5400zl/E8200zl switches with the other power supplies. The J9306A operates at 110-127V supplying 300 watts of PoE/PoE+ power, and 200-240V supplying 900 watts of PoE/PoE+ power.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples Source of Power Watts Available at 200-240V # of Ports Powered and Average watts/Port Redundant # of Ports Powered and Average watts/Port Two Internal PoE/ 1800 (without PoE+ Power redundancy) Supplies (J9306A) 60 @ average 30 W each 116 @ average 15.4 W each 144 @ average 7.5 W each 144 @ average 4.0 W each 30 @ average 30 W each 58 @ average 15.4 W each 120 @ average 7.5 W each 144 @ average 4.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples ProCurve 5412zl/8212zl Configurations using the Power Supply Shelf The Power Supply Shelf can be connected to the 5412zl/8212zl to supply extra or redundant PoE power to the PoE modules installed in the 5412zl/8212zl. Either EPS port on the Power Supply Shelf can be connected to either EPS port on the switch. To avoid confusion, it is recommended that EPS 1 of the Power Supply Shelf be connected to EPS 1 of the switch.
Planning and Implementation for the E5400zl/E8200zl Switches Configuration Examples In this configuration, EPS 2 of the Power Supply Shelf can be connected to either EPS 1 or EPS 2 of either switch. To Power Source To Power Source EPS 1 To Power Source To Power Source To Power Source 5412zl 8212zl EPS 2 EPS 2 EPS Cables EPS 1 Figure 13-22.
14 Infrastructure Requirements Air conditioning Power supplies create a great amount of heat. Ensure you have enough cool air to maintain an ambient temperature between 0°C to 50°C (32°F to 131°F) around the switch devices inside the rack or equipment closet. If you are installing any of the X2 transceivers the operating ambient temperature should not exceed 40°C (104°F). See transceiver specifications in the installation guide for your switch. A typical 48 port PoE switch BTU rating is approximately 920.
Infrastructure Requirements Physical Space Many switches come with dual power ratings (110 or 220 volt operation). Therefore planning for power requirements is critical. If a wiring closet currently only supplies 110 volts it must be determined whether or not to operate the switch at 110 volts or 220 volts. You not only need to plan for voltage requirements but amperage requirements. PoE switches can be double or triple the amperage draw compared to a non-PoE switch.
Glossary Glossary active PoE port - PoE-enabled port connected to a PD and currently delivering power. priority class - Refers to the type of power prioritization where the switch uses Low (the default), High, and Critical priority assignments to determine which groups of ports will receive power. Note that power priority rules apply only if PoE provisioning on the switch becomes oversubscribed.
A Planning Considerations This appendix is divided into five sections: ■ General Considerations ■ ■ ■ ■ Specific Considerations for the 2910al-PoE Switches Specific Considerations for the 3500-PoE Switches Specific Considerations for the 3500yl-PWR Switches Specific Considerations for the E5400zl/E8200zl Switches These lists are in no way exhaustive, however answers to these and other questions will help define how many and what types of switches are needed to implement a PoE configuration.
Planning Considerations Specific Considerations for the 2910al-PoE Switches Specific Considerations for the 2910alPoE Switches The following is an example list of considerations during the planning phase specific to the 2910al Switches: ■ What if power is lost to the switch? • Power for the switch to operate (system power) • Power for PoE devices ■ Which devices to plug into which ports and with what priorities? • Port prioritization • Port priority class • Total watts available (382) ■ Which bank of 24 po
Planning Considerations Specific Considerations for the 3500-PoE Switches Specific Considerations for the 3500-PoE Switches The following is an example list of considerations during the planning phase specific to the 3500-PoE Switches: ■ What if power is lost to the switch? • Power for the switch to operate (system power) • Power for PoE devices ■ Which devices to plug into which ports and with what priorities? • Port prioritization • Port priority class • Reserve watts • Total watts available (398) ■ Whic
Planning Considerations Specific Considerations for the 3500yl-PWR Switches Specific Considerations for the 3500ylPWR Switches The following is an example list of considerations during the planning phase specific to the 3500yl Switches: ■ What if power is lost to the switch? • Power for the switch to operate (system power) • Power for PoE devices ■ Which devices to plug into which ports and with what priorities? • Port prioritization • Port priority class • Reserve watts • Total watts available (398) ■ Whi
Planning Considerations Specific Considerations for the 3500yl-PoE+ Switches Specific Considerations for the 3500ylPoE+ Switches The following is an example list of considerations during the planning phase specific to the 3500yl Switches: ■ What if power is lost to the switch? • Power for the switch to operate (system power) • Power for PoE devices ■ Which devices to plug into which ports and with what priorities? • Port prioritization • Port priority class • Reserve watts • Total watts available (398) ■ W
Planning Considerations Specific Considerations for the E5400zl/E8200zl Switches Specific Considerations for the E5400zl/ E8200zl Switches The following is an example list of considerations during the planning phase specific to the E5400zl/E8200zl Switches: ■ What if power is lost to the switch? • Power for the switch to operate (system power) • Power for PoE devices ■ Which devices to plug into which ports, modules, and with what priorities? • Slot prioritization • Port prioritization • Port priority clas
Index Numerics 1500 W PoE+ zl power supply … 13-28 2910bl specific consideration … A-2 3500 switch planning config … 10-1 3500-PoE specific consideration … A-3 3500yl specific consideration … A-4 3500yl-PoE+ specific consideration … A-5 5300 xl PoE module … 2-25 5400zl/8200zl switches planning and implementation … 13-1 C cable data pairs … 1-4 power through … 1-4 spare pairs … 1-4 class method priority … 2-4 HP Switch v2 zl 20 port Gig-T PoE+ Module … 1-27 HP Switch v2 zl 20 port PoE+ & 2-port SFP+ Module
planning … 3-1, 4-1, 5-1, 6-1, 7-1, 8-1, 9-1, 10-1, 11-1, 12-1, 13-1 PoE configuration … 10-2, 11-2, 11-7, 12-3 E5400zl/E8200zl config … 13-2 general considerations … A-1 planning … 3-1, 4-1, 5-1, 6-1, 7-1, 8-1, 9-1, 10-1, 11-1, 12-1, 13-1 port-number priority … 2-4 power requirements … 2-10 priority class … 2-5 product capabilities … 1-5 using LLDP … 2-18 PoE allocation using LLDP … 2-15–2-16, 2-18–2-21 PoE power 3500 maximum power … 2-17 3500 requirements … 2-17 external for 3500-48-PoE … 10-6 PoE power s
ProCurve Switch zl 24 port PoE/PoE+ Module … 1-26 provisioning power, switch … 2-8 R redundancy … 1-24 conceptual example … 13-2 full … 13-2 N+1 … 13-2 with 5406zl/8206zl … 13-2 S supported products … A-1 switch E3800 E3800-24G-2XG-PoE+ switch … 1-17–1-18 E3800-48G-4XG-PoE+ switch … 1-17–1-18 switch PoE operation … 2-2 switch priority class … 2-7 switches 2626-PWR, 2650-PWR, 2600-8-PWR, Series 2600PWR Switches … 1-7–1-8 system power 5412zl/8212zl … 13-5 E5412zl/E8212zl … 13-6 T threshold configuing globa
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