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3par t400 manualThe installati on of HP 3P AR equipment is to be perfor med by qualified techni ci ans who are author i z ed by HP to install stor age s ys tems and the ir hard w are components. Author i z ed technic ians include HP service engineers, V alue A dded R eseller s (V ARs), certifi ed self-maintaining cu stomer s, and authori z ed third-party field techni ci ans. HP P art Number: QL22 6 -9 7 1 44 P ublished: Marc h 20 1 4 1 2 3. 221 Summary of content (221 pages) Page 1 HP 3PAR T-Class Installation and Deinstallation Guide Abstract This guide describes installation and deinstallation procedures for the HP 3PAR T-Class Storage System. The installation of HP 3PAR equipment is to be performed by qualified technicians who are authorized by HP to install storage systems and their hardware components. Authorized technicians include HP service engineers, Value Added Resellers (VARs), certified self-maintaining customers, and authorized third-party field technicians. The only warranties for HP products and services are set forth in the express warranty statements accompanying such products and services. Nothing herein should be construed as constituting an additional warranty. HP shall not be liable for technical or editorial errors or omissions contained herein. Page 3 Contents I Preinstallation.8 1 Preparing for Storage System Installation.9 Advisories.9 Preinstallation Planning.9 Configuration Planning. Page 4 Unpacking and Inserting the Drive Magazines.58 Unpacking Drive Magazines.58 Drive Magazine Loading Pattern.59 Inserting the Drive Magazines.61 Installing Drive Cage Filler Panels. Page 5 Mixed Connectivity Setup.126 Modem Setup.132 Secure Site Setup.139 Installing HP 3PAR OS Files. Page 6 Bulgarian recycling notice.181 Czech recycling notice.181 Danish recycling notice.181 Dutch recycling notice.http://sabagdasarov.ru/upload/4-speed-manual-transmission-vs-5-speed.xml

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Page 12 Split With a split network topology, the storage system is on the internal customer network, but the storage system communicates with the service processor on a dedicated private network segment (Figure 3 (page 12)). 3PAR assigns the IP address to the private segment. Page 13 processor and HP Central or a local service provider can be made using the customer network and the Internet, or through a point-to-point connection using a modem. Connections using the customer network pass through the customer firewall. Connections using a modem, bypass the customer firewall. Page 14 Providing for Service Access HP 3PAR Storage System cabinets feature locking rear doors, removable side panels and fascias to improve access for installing, cabling, and servicing components. See Table 2 (page 14) for storage system cabinet dimensions. Page 16 Tile Cutout Specifications Figure 6 (page 16) contains the recommended tile cutout specifications for storage system cabinets. WARNING! To prevent potential collapse, loaded floor panels that have cutouts to facilitate cable routing may require additional reinforcement. Figure 6 Tile Cutout Specifications for a Storage System Cabinet Resting on Two Floor Tiles Meeting Electrical Requirements Before placing a storage system, verify the operating site has the necessary electrical circuitry. Page 17 HP 3PAR cabinets contain four power distribution units (PDU). Each PDU requires service from a dedicated single-phase 200-240 VAC 30-A grounded electrical circuit. HP recommends a redundant AC configuration using independent sources to provide a dedicated, grounded electrical circuit to each PDU. Page 18 Figure 8 Rear View of the Power Domains Within the Controller Nodes and Drive Chassis WARNING. To avoid possible injury, damage to storage system equipment, and potential loss of data, do not use the surplus power outlets in the storage system PDUs.http://www.fronzek-gutheil.de/UserFiles/4-speed-new-process-overdrive-manual-transmission.xml Never use outlets in the PDUs to power components that do not belong to the storage system or to power storage system components residing in other cabinets. NOTE: Illustrations in this chapter show sample systems and may not match a particular storage system configuration. Identifying Storage System Components Figure 11 (page 24) and Figure 12 (page 25) identify the major components of an T400 Storage System in a 2M (40U) 3PAR cabinet. Page 24 Figure 11 The Front of a T400 Storage System 24 Storage System Physical Layout and Numbering Page 25 Figure 12 The Rear View of a T400 Storage System Service Processor Placement A service processor designed to support all actions required for the maintenance of the storage system also resides at the bottom of the cabinet to provide real time, automated monitoring. The service processor allows HP to diagnose and resolve potential problems remotely. The service processor is usually installed directly above the PDUs and below the battery tray (Figure 13 (page 26)). Page 26 Figure 13 Placement of the Service Processor (T400) NOTE: For T800 Storage Systems, the service processor is located above the system backplane, below the lowest drive chassis but above the upper battery tray. Figure 15 (page 28) illustrates service processor placement for a T800. When a cabinet does not include a service processor, a filler panel covers the area of the cabinet that the service processor normally occupies. Page 27 Figure 14 Numbering of Chassis Bays in the Cabinet2 A storage system can be housed in a single cabinet or multiple cabinets. When multiple cabinets are required, the first cabinet (the controller node cabinet) holds the system backplane populated with controller nodes. Any additional cabinets, or drive chassis cabinets, hold the additional drive chassis that do not fit into the controller node cabinet. Page 28 Figure 15 Controller Node Cabinet Component Layout by Storage System Model3 3 3.http://www.drupalitalia.org/node/67597 When a 1U service processor is present, a 1U filler panel resides immediately above or below the unit. Page 29 Figure 16 Drive Chassis Cabinet Component Layout PDU Numbering For each cabinet, the four Power Distribution Units (PDU) occupy the lowest chassis bay in the cabinet. Page 30 Figure 17 Numbering of PDUs NOTE: For T800 systems, the PDUs are positioned back-to-back to only occupy two units of space at the bottom of the cabinet instead of the standard four units of space. PDUs are accessible from both the front and the rear of the system. “Controller Node Cabinet Component Layout by Storage System Model3” (page 28) illustrates PDU placement for a T800 system. Page 31 Figure 19 Battery Backup Unit BBU placement and numbering schemes vary according to the type of components used in the system. A battery tray may hold a maximum of four BBUs. The number of BBUs and battery trays in a system depends on the number of controller nodes installed (Table 9 (page 31)). Page 32 Figure 20 Battery Backup Units Have Batteries Resting Vertically When facing the rear of the storage system, the BBUs are numbered from right to left, 0 through 3. When two battery trays are present, the upper tray is numbered 0 and the lower tray is numbered 1 (Figure 21 (page 32)). Figure 21 BBU Numbering Scheme Controller Node Numbering A T-Class Storage System may contain two, four, six, or eight controller nodes per system. Page 33 Figure 22 Numbering of Controller Nodes in an T800 Backplane As shown in Figure 23 (page 34), a controller node contains six PCI slots. These slots accept PCI adapters such as quad-port Fibre Channel adapters, iSCSI adapters, and Ethernet adapters. The controller node also has a management Ethernet port (E0), a dedicated Remote Copy over IP (E1), and a maintenance port (C0). Page 34 Figure 23 Numbering for Fibre Channel Adapters in the Controller Node PCI Slots Each Fibre Channel adapter in a PCI slot has four ports. Each iSCSI adapter in a PCI slot has two ports.http://arredomilano.com/images/3par-inform-os-cli-administratoru2019s-manual.pdf Page 35 Figure 24 Control Cache and Data Cache DIMMs in the Controller Node Numbers for controller nodes and their components are assigned in the order indicated in Table 10 (page 35). Table 10 Numbering System for Controller Nodes and Their Components The Following Components. Drive chassis are always placed above the storage system backplane enclosure and numbered according to their position in relation to the backplane, as shown in Figure 25 (page 36). Table 11 Numbering System for Drive Chassis Components The Following Components. Are Numbered. Running from. Drive cages 0,1,. Page 38 Table 11 Numbering System for Drive Chassis Components (continued) The Following Components. Are Numbered. Running from. Page 39 Figure 28 Pattern for Loading Initial Drive Magazines Into the Drive Chassis NOTE: See “Installing the Drive Magazines” (page 56), for further instructions on drive magazine allocation. Power Supply Numbering The cabinets are divided into upper and lower power domains containing drive cages or controller nodes and dedicated power supplies. The drive cages and controller nodes depend on these power supplies connecting to PDUs for power. Page 40 Figure 29 Numbering of Power Supplies Within the Power Domains 40 Storage System Physical Layout and Numbering Page 41 Part II Installation Page 42 3 Setting Up the Storage System This chapter provides instructions for unpacking and placing HP 3PAR cabinets. It also includes instructions for removing the rear door, removing side panels, and adjusting the power cabling configuration. CAUTION: Before unpacking and placing a cabinet, establish an operating site to meet the physical, electrical, and atmospheric requirements for a storage system. Page 43 1. Locate the front of the shipping container (“The Front of the Cabinet Shipping Container ” (page 43)) and unlatch the four rotary latches securing the front panel. Figure 30 The Front of the Cabinet Shipping Container 2. To unlatch the rotary latches, raise the levers and turn them counterclockwise one half turn, as shown in “Unlatching a Rotary Latch” (page 164). Page 44 Figure 31 Unlatching a Rotary Latch 3. 4. Lower the front panel of the shipping container to form a ramp. Remove the packing foam from the front of the storage system (“Removing Packing Foam ” (page 44)). Figure 32 Removing Packing Foam 5. 44 Grasp the two straps on either side of the cabinet and carefully pull the cabinet out of the container (“Location of Straps ” (page 45)). Page 45 Figure 33 Location of Straps 6. 7. Carefully guide the cabinet down the ramp. Remove the plastic ESD-preventative packing materials from the cabinet and place into the shipping container for reuse. NOTE: Retain packing materials, including wooden crates and pallets, for reuse. Placing the Storage System After following the guidelines to establish a safe operating site as described in Chapter 1 (page 9), place the storage system in the operating location. Page 46 1. Use an adjustable wrench and turn clockwise to lower each foot until the weight of the cabinet rests on the leveling feet instead of the casters (“Lowering a Leveling Foot” (page 46)). Figure 34 Lowering a Leveling Foot 2. Lock the feet in place by turning the locking nut on each foot counterclockwise until tight with an adjustable wrench (“Tightening the Locking Nut” (page 46)). Pull the fascia to remove from cabinet. Figure 36 Removing a Front Fascia Removing Locking Fascias HP 3PAR cabinets features optional locking left and right fascias. HP recommends locking both fascias during operation. The locking fascias prevent the bezels from being removed and restrict access to the drive chassis and drive magazines. Page 48 1. Use the provided key to unlock the left and right fascia (“Location of Fascia Locks” (page 48)). Locating the Wrist Grounding Strap To prevent damage from electrostatic discharge, it is necessary to wear an Electrostatic Discharge (ESD) wrist grounding strap during installation and maintenance of the storage system. Page 49 Figure 38 Removing a Bezel from the Storage System Removing the Rear Door HP 3PAR cabinets feature a locking rear door. HP recommends locking the rear door during operation. At the time of delivery, the rear door is unlocked. The key is taped to the inside of the rear door. The rear door is also removable to improve access to the rear of the system during installation and maintenance. To remove the rear door: 1. Page 50 Figure 39 Lift-Off Hinges on the Door 3. 50 Release the bottom hinge by squeezing together the two release pins on the hinge and sliding the pins to the right (“Releasing the Hinge on the Rear Door of the Cabinet” (page 51)). Page 51 Figure 40 Releasing the Hinge on the Rear Door of the Cabinet 4. After releasing the bottom hinge, release the top hinge and pull the door away from the cabinet to remove it (“Removing the Rear Door” (page 51)). Figure 41 Removing the Rear Door Removing Side Panels In addition to removing the rear door, remove one or more side panels prior to continuing with the installation. Page 53 There may be instances when an operating site lacks the capacity to provide each PDU in the system with a dedicated electrical circuit. HP recommends choosing an alternate operating site which meets all of the requirements detailed in Chapter 1 (page 9). The standard cabling configuration for storage systems in HP 3PAR cabinets supports redundant AC within the system through AC cords situated between the power domains of the system. Page 54 Figure 43 Redundant Power Cabling Diagram (T400 Node Cabinet or Drive Expansion Cabinet) 54 Setting Up the Storage System Page 55 Figure 44 Redundant Power Cabling Diagram (T800 Node Cabinet) Adjusting Power Cables 55 Page 56 4 Installing the Drive Magazines This chapter describes how to install drive magazines after placing a system at the operating site. CAUTION: To avoid damaging the system equipment, do not relocate or move the storage system over uneven surfaces with the drive magazines installed. NOTE: If the cabinet has locking fascias, first remove the fascias to access the bezel. See “Storage System Fascias” (page 46). A wrist grounding strap is provided with the cabinet. Page 58 Figure 47 Numbering of Drive Chassis Components Figure 48 Numbering of Disks on the Drive Magazines Unpacking and Inserting the Drive Magazines The following sections describe how to unpack and install drive magazines into the storage systems. Unpacking Drive Magazines The drive magazines arrive in a shipping container. Containers hold a maximum of 30 magazines. Magazines are packaged in protective material to prevent damage from electrostatic discharge. To unpack the drive magazines: 1. Page 59 3. To unlatch a rotary latch, raise the lever and turn it counterclockwise, as shown in “Unlatching a Rotary Latch” (page 59). Figure 49 Unlatching a Rotary Latch 4. 5. Identify the drive magazine sizes. See the HP 3PAR Systems Assurance Document for additional information about drive magazine sizes and placement for your specific storage system configuration. Remove a magazine from the container. Slide the magazine out of the container protective sleeve. Page 60 Figure 50 Pattern for Loading Initial Drive Magazines into the Drive Chassis NOTE: Depending on the number of drive chassis and drive magazines in your system, the drive magazine loading pattern may differ than the pattern depicted in “Pattern for Loading Initial Drive Magazines into the Drive Chassis” (page 60). Table 12 Procedure for Loading Drive Magazines 60 Step Procedure 1 Beginning with the drive chassis nearest to the bottom of the cabinet, insert a magazine into slot 0 of the drive cage. Page 61 Inserting the Drive Magazines To insert the drive magazines: 1. Locate the drive chassis nearest to the bottom of the cabinet and insert the magazine into slot 0 within that drive chassis. Use the notch at the top of the drive bay as a guide while inserting the magazine (“Inserting a Drive Magazine Into a Drive Chassis” (page 61)) NOTE: For systems that occupy multiple cabinets, drive chassis numbers continue at the bottom of the next cabinet and progress through the top of the cabinet. Page 62 to fully seat the drive magazine in the chassis. When fully seated, the drive handle of the magazine rests against the front of the drive chassis housing. CAUTION: Drive magazines should glide in easily. If a drive magazine does not insert smoothly, do not force it. Check if the magazine is properly aligned with the guide notch at the top of the drive bay and apply moderate pressure toward the left side of the magazine while inserting. Page 63 If the drive magazine allocation for this system differs from the standard allocation pattern, it may be necessary to remove some drive magazine filler panels before installing the drive magazines. Insert a screwdriver into the filler panel slot and leverage the drive magazine filler panel out. To install drive magazine filler panels, place a drive magazine filler panel over the front opening of each empty drive bay in the system. Page 64 5 Checks and Setup before Powering On the Storage System This chapter describes how to connect the power cords and complete the power on sequence for an HP 3PAR T-Class Storage System. Checking Power Cord Connections The storage systems arrive with all internal power cords configured and connected. Page 65 Figure 55 PDU Power Banks Each power bank supplies a maximum current of 12A at 220 VAC. PDUs have a cable tie system securing the AC cords to prevent accidental disconnection. Power supplies have cord locks securing the AC cords to prevent accidental disconnection (Figure 56 (page 65) and Figure 57 (page 66)). Page 66 Figure 57 Cord Lock with Adjustable Fastener Strap on Drive Chassis Power Supply Before powering on the storage system, check the cord locks on the power supplies to confirm the AC cords have become loose during shipping. Also check the AC cords and cable ties on the PDUs to verify cord connections are secured. Redundant Power Before powering on the storage system, verify the system has a valid redundant power configuration. In addition, verify each PDU connects to an independent AC input source. Page 67 Figure 58 Redundant Power Configuration (T400) NOTE: “Redundant Power Configuration (T800)” (page 68) applies only to the T800 configuration with front and rear PDUs. Page 68 Figure 59 Redundant Power Configuration (T800) Checking Battery Backup Unit Cable Connections Battery cables connect the storage system Battery Backup Units (BBU) to the controller nodes. The BBUs are housed in one or more battery trays sitting above and below the controller nodes. A battery tray can hold a maximum of four BBUs (Figure 60 (page 69)). Page 69 Figure 60 Lower Battery Tray and BBUs NOTE: BBUs are inserted in the front of the storage system. Each BBU contains two independently functioning batteries. BBUs have batteries resting vertically, with battery A above battery B. (Figure 20 (page 32)). Figure 61 Battery Backup Units Have Batteries Resting Vertically Storage systems in HP 3PAR cabinets arrive with all BBUs installed and cabled. Page 70 Figure 62 Battery Backup Unit Cabling Configurations for Storage Systems Before powering on the storage system, verify the battery cables have not loosen during shipping. Verify the safety breakers on all four of the PDUs are set to the OFF position, as shown in “Setting the Safety Breakers to the OFF Position” (page 71). Figure 63 Setting the Safety Breakers to the OFF Position 3. 4. Page 72 Figure 64 Routing the Main Power Cords NOTE: To route power cords through the upper access opening of the cabinet, it is first necessary to remove one or both side panels as described in “Removing Side Panels” (page 51). 6. Plug each of the main power cords into a dedicated single-phase 200-240 VAC 30-A grounded electrical circuit. Page 73 Figure 65 Preventing Accidental Disconnection of the Main Power Cord (NEMA L6-30) WARNING. The main power cords include safety features to prevent plugging them into electrical circuits not compatible with the storage system. To prevent serious injury to people and damage to equipment, do not override this feature by using outlet adapters, altering power cords, or modifying power receptacle connectors. Page 74 1. Align the rear door with the two hinges near the top and bottom of the cabinet frame, as shown in “Aligning the Rear Door with the Hinges” (page 74). Page 75 2. Engage the hinges by squeezing the two release pins on the hinges and pushing the hinges to the left, as shown in “Engaging the Hinges on the Rear Door” (page 75). Figure 67 Engaging the Hinges on the Rear Door Replacing the Side Panels and Filler Panels Replace any side panels or filler panels removed during cabling and positioning of the storage system. Page 76 1. Use an adjustable wrench to turn the upper locking nuts clockwise completely (“Releasing the Locking Nut” (page 76)). Figure 68 Releasing the Locking Nut 2. Using an adjustable wrench, turn each foot counterclockwise until completely raised (“Raising the Leveling Foot” (page 76)). Figure 69 Raising the Leveling Foot NOTE: If the operating site has raised floor tiles with cutouts to facilitate cable routing, position the cabinets over the cutouts in the tiles. Page 77 Verifying Acclimatization Before being powered on, the storage system may require up to 24 hours to acclimatize to the new operating environment when outside-to-inside conditions vary greatly. If there is a possibility the storage system or its components may have experienced environmental changes during transit, verify the amount of acclimatization time for the storage system before proceeding with the power-on sequence. Page 78 6. After approximately 10 minutes, check the status of all LEDs for proper operation. Refer to “Understanding LED Status” (page 79) for specifics. NOTE: At this time, the node system LEDs appear solid green because the system has not been initialized. Page 79 6 Understanding LED Status Using the Component LEDs HP 3PAR T-Class Storage System components have LEDs to indicate the hardware is properly functioning and to help identify errors. These LEDs help diagnose basic hardware problems. You can quickly identify hardware problems by examining the LEDs on all the components. Use the tables and diagrams in the following sections to verify the hardware is properly functioning. Page 80 Figure 72 Connections and LEDs on the DC4 Drive Cage FC-AL Modules Consult Table 13 (page 80) to verify proper functioning of the DC4 drive cage FC-AL modules. Table 13 Drive Cage DC4 FC-AL Module LED Displays LED Appearance Meaning RX Steady green light Indicates the presence of a small form-factor pluggable optical transceiver (SFP) and a valid signal from the node. No light Indicates there is not a connection to the node or an SFP is not installed. Otherwise, indicates FC-AL module error or other cage error. Page 82 Table 14 Drive Magazine LED Displays LED Appearance Meaning DC4 Drive Magazine Status Steady green light Indicates the drive magazine is functioning properly. Steady amber light Indicates a drive magazine error, or one or more drives are bypassed on at least one path. Disk status DC4 Hot-plug Quick flashing, or 20 percent-on and Indicates disk is not spun up but is 80 percent-off green light functioning. Steady green light Indicates the disk is spun up and waiting for a command. Page 83 Consult Table 15 (page 83) to verify proper functioning of controller nodes. Table 15 Controller Node LED Displays LED Appearance Meaning Disk Hot-plug Steady amber light Indicates the internal disk is ready for hot-plug. No light. Indicates the internal disk is not ready for hot-plug. Steady amber light In combination with the Status LED blinking green three times per second, indicates the controller node is prepared for removal. Page 84 Figure 75 4-Port Fibre Channel LEDs Consult Table 16 (page 84) to verify proper function of the Fibre Channel adapter LED. Table 16 Fibre Channel Port Status LED Indications (4-Port Adapter) LED Appearance Meaning No light Wake-up Failure (broken device). Steady green light Normal -- Link up at 2 or 4 Gbps. Flashing green light Link down or disconnected. QLogic iSCSI Port LEDs The QLogic iSCSI adapter contains two ports and each port has one LED. Page 85 Figure 76 iSCSI Adapter LEDs Consult Table 17 (page 85) to verify the proper functioning of QLogic iSCSI adapter LEDs. Table 17 iSCSI Adapter Port LED Indications LED Appearance Meaning Steady green Indicates a link is established. Flashing green Indicates receiving or transmitting activity. Off Indicates no connection or active link. Ethernet Adapter LEDs The controller node Ethernet adapter has two LEDs (Figure 77 (page 86)). Page 86 Figure 77 Ethernet Adapter LEDs Consult Table 18 (page 86) to verify the proper functioning of Ethernet adapter LEDs. Flashing green light Data activity. Speed Power Supply LEDs Power supply units are located at the rear of all drive cages and controller nodes. Page 87 Figure 78 Power Supply LEDs NOTE: The appearance of the drive chassis and controller node power supplies can vary slightly according to manufacturer and location. Consult Table 19 (page 87) to verify proper operation of the power supplies. Table 19 Power Supply LED Displays LED Appearance Meaning Power supply status Steady green light Indicates the power is on. Steady amber light Indicates a power supply error. No light Indicates a broken connection to the AC power source. Page 88 BBUs contain two batteries, labeled battery A and battery B. The BBUs also include the following LEDs (Figure 79 (page 88)): Figure 79 Battery Backup Unit LEDs (Magnetek) Consult Table 20 (page 88) to verify proper functioning of the BBUs. Table 20 Battery Backup Unit LED Displays LED Appearance Meaning Battery A status LED Steady green light Indicates battery A is charged. Flashing green light Indicates the battery is undergoing a test. Steady amber light Indicates a battery error. Page 89 Service Processor LEDs Wintec Service Processor The Wintec service processor LEDs are defined in the following section. The LED's are located at the top of the Wintec service processor (Figure 81 (page 89)). Figure 81 Wintec Service Processor LEDs Consult Table 21 (page 89) to verify proper functioning of the Wintec service processor displays. Table 21 Wintec Service Processor LED Displays LED Appearance Meaning Hard Disk No light Indicates no hard drive activity. Page 90 Figure 82 Supermicro Service Processor LEDs Consult Table 22 (page 90) to verify proper functioning of the Supermicro service processor displays. Table 22 Supermicro Service Processor LED Displays LED Appearance Meaning Overheat No light Indicates the system is normal Steady red light Indicates the system is overheated No light Indicates no network activity Flashing green light Indicates network activity Steady green light Indicates network is linked No light Indicates no network activity. Page 91 Consult Table 23 (page 91) to verify proper functioning of the Supermicro II service processor displays. Table 23 Supermicro II Service Processor Front-Panel Displays LED Appearance Meaning Power No light Indicates the service processor is off. Steady green light Indicates the service processor is on. No light Indicates no hard drive activity. Flashing amber light Indicates hard drive activity. No light Indicates the port is not connected. Page 92 7 Initializing the Storage System Software This chapter describes how to complete the installation of a storage system by setting up and configuring the storage system software and service processor software. You must execute these scripted setup procedures from the maintenance PC after powering on the system. NOTE: In this and other chapters, the command-line examples use bold type to indicate user input and to denote variables. Examples may not match the exact output of your system. Page 93 2. From the console menu, select option 1 for Out of The Box Procedure. 3PAR Console Menu 1400293-1 3.1.1.xxx 1. Out Of The Box Procedure 2. Run ootb-stress-analyzer 3. Re-enter network configuration 4. Update the CBIOS 5. Enable or disable CLI error injections 6. Perform an IDE rescue 7. Set up the system to wipe and rerun ootb 8. Cancel a wipe 9. Perform a deinstallation 10. Update the system for recently added hardware (admithw) 11. Check system health (checkhealth) 12. Page 94 3. Set a. b. c. d. up the time zone for the operating site as follows: Select a location from the list, type the corresponding number, and press ENTER. Select a country, type the corresponding number, and press ENTER Select a time zone region, type the corresponding number, and press ENTER. Verify the time zone settings are correct, type 1, and press ENTER. NOTE: The system automatically makes the time zone change permanent. Page 95 7. Verify the number of drive magazines and physical disks in the storage system. Examining the port states. All ports are in acceptable states. Examining state of new disks.