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Install and maintain

Replace the real-time clock battery - AFF C400

Contributors

You replace the real-time clock (RTC) battery in the controller module so that your system's services and applications that depend on accurate time synchronization continue to function.

  • You can use this procedure with all versions of ONTAP supported by your system

  • All other components in the system must be functioning properly; if not, you must contact technical support.

Step 1: Shut down the impaired controller

You can shut down or take over the impaired controller using different procedures, depending on the storage system hardware configuration.

Option 1: Most configurations

To shut down the impaired controller, you must determine the status of the controller and, if necessary, take over the controller so that the healthy controller continues to serve data from the impaired controller storage.

About this task
  • If you have a SAN system, you must have checked event messages (cluster kernel-service show) for the impaired controller SCSI blade. The cluster kernel-service show command (from priv advanced mode) displays the node name, quorum status of that node, availability status of that node, and operational status of that node.

    Each SCSI-blade process should be in quorum with the other nodes in the cluster. Any issues must be resolved before you proceed with the replacement.

  • If you have a cluster with more than two nodes, it must be in quorum. If the cluster is not in quorum or a healthy controller shows false for eligibility and health, you must correct the issue before shutting down the impaired controller; see Synchronize a node with the cluster.

Steps
  1. If AutoSupport is enabled, suppress automatic case creation by invoking an AutoSupport message: system node autosupport invoke -node * -type all -message MAINT=<# of hours>h

    The following AutoSupport message suppresses automatic case creation for two hours: cluster1:> system node autosupport invoke -node * -type all -message MAINT=2h

  2. Disable automatic giveback from the console of the healthy controller: storage failover modify –node local -auto-giveback false

    Note When you see Do you want to disable auto-giveback?, enter y.
  3. Take the impaired controller to the LOADER prompt:

    If the impaired controller is displaying…​ Then…​

    The LOADER prompt

    Go to the next step.

    Waiting for giveback…​

    Press Ctrl-C, and then respond y when prompted.

    System prompt or password prompt

    Take over or halt the impaired controller from the healthy controller: storage failover takeover -ofnode impaired_node_name

    When the impaired controller shows Waiting for giveback…​, press Ctrl-C, and then respond y.

Option 2: Controller is in a two-node MetroCluster

To shut down the impaired controller, you must determine the status of the controller and, if necessary, switch over the controller so that the healthy controller continues to serve data from the impaired controller storage.

About this task
  • You must leave the power supplies turned on at the end of this procedure to provide power to the healthy controller.

Steps
  1. Check the MetroCluster status to determine whether the impaired controller has automatically switched over to the healthy controller: metrocluster show

  2. Depending on whether an automatic switchover has occurred, proceed according to the following table:

    If the impaired controller…​ Then…​

    Has automatically switched over

    Proceed to the next step.

    Has not automatically switched over

    Perform a planned switchover operation from the healthy controller: metrocluster switchover

    Has not automatically switched over, you attempted switchover with the metrocluster switchover command, and the switchover was vetoed

    Review the veto messages and, if possible, resolve the issue and try again. If you are unable to resolve the issue, contact technical support.

  3. Resynchronize the data aggregates by running the metrocluster heal -phase aggregates command from the surviving cluster.

    controller_A_1::> metrocluster heal -phase aggregates
    [Job 130] Job succeeded: Heal Aggregates is successful.

    If the healing is vetoed, you have the option of reissuing the metrocluster heal command with the -override-vetoes parameter. If you use this optional parameter, the system overrides any soft vetoes that prevent the healing operation.

  4. Verify that the operation has been completed by using the metrocluster operation show command.

    controller_A_1::> metrocluster operation show
        Operation: heal-aggregates
          State: successful
    Start Time: 7/25/2016 18:45:55
       End Time: 7/25/2016 18:45:56
         Errors: -
  5. Check the state of the aggregates by using the storage aggregate show command.

    controller_A_1::> storage aggregate show
    Aggregate     Size Available Used% State   #Vols  Nodes            RAID Status
    --------- -------- --------- ----- ------- ------ ---------------- ------------
    ...
    aggr_b2    227.1GB   227.1GB    0% online       0 mcc1-a2          raid_dp, mirrored, normal...
  6. Heal the root aggregates by using the metrocluster heal -phase root-aggregates command.

    mcc1A::> metrocluster heal -phase root-aggregates
    [Job 137] Job succeeded: Heal Root Aggregates is successful

    If the healing is vetoed, you have the option of reissuing the metrocluster heal command with the -override-vetoes parameter. If you use this optional parameter, the system overrides any soft vetoes that prevent the healing operation.

  7. Verify that the heal operation is complete by using the metrocluster operation show command on the destination cluster:

    mcc1A::> metrocluster operation show
      Operation: heal-root-aggregates
          State: successful
     Start Time: 7/29/2016 20:54:41
       End Time: 7/29/2016 20:54:42
         Errors: -
  8. On the impaired controller module, disconnect the power supplies.

Step 2: Remove the controller module

To access components inside the controller module, you must remove the controller module from the chassis.

  1. If you are not already grounded, properly ground yourself.

  2. Release the power cable retainers, and then unplug the cables from the power supplies.

  3. Loosen the hook and loop strap binding the cables to the cable management device, and then unplug the system cables and SFPs (if needed) from the controller module, keeping track of where the cables were connected.

    Leave the cables in the cable management device so that when you reinstall the cable management device, the cables are organized.

  4. Remove the cable management device from the controller module and set it aside.

  5. Press down on both of the locking latches, and then rotate both latches downward at the same time.

    The controller module moves slightly out of the chassis.

    Remove controller module

    Callout number 1

    Locking latches

    Callout number 2

    Controller moves slightly out of chassis

  6. Slide the controller module out of the chassis.

    Make sure that you support the bottom of the controller module as you slide it out of the chassis.

  7. Place the controller module on a stable, flat surface.

Step 3: Replace the RTC battery

You need to locate the RTC battery inside the controller module, and then follow the specific sequence of steps. See the FRU map inside the controller module for the location of the RTC battery.

You can use the following animation, illustration, or the written steps to replace the RTC battery.

Animation- Replace the RTC battery
Remove RTC battery

Callout number 1

Middle riser

Callout number 2

Remove RTC battery

Callout number 3

Seat RTC battery

  1. If you are not already grounded, properly ground yourself.

  2. Open the air duct:

    1. Press the locking tabs on the sides of the air duct in toward the middle of the controller module.

    2. Slide the air duct toward the back of the controller module, and then rotate it upward to its completely open position.

  3. Locate, remove, and then replace the RTC battery:

    1. Using the FRU map, locate the RTC battery on the controller module.

    2. Gently push the battery away from the holder, rotate it away from the holder, and then lift it out of the holder.

      Note Note the polarity of the battery as you remove it from the holder. The battery is marked with a plus sign and must be positioned in the holder correctly. A plus sign near the holder tells you how the battery should be positioned.
    3. Remove the replacement battery from the antistatic shipping bag.

    4. Note the polarity of the RTC battery, and then insert it into the holder by tilting the battery at an angle and pushing down.

  4. Visually inspect the battery to make sure that it is completely installed into the holder and that the polarity is correct.

  5. Close the air duct.

Step 4: Reinstall the controller module and setting time/date after RTC battery replacement

After you replace a component within the controller module, you must reinstall the controller module in the system chassis, reset the time and date on the controller, and then boot it.

  1. If you have not already done so, close the air duct or controller module cover.

  2. Align the end of the controller module with the opening in the chassis, and then gently push the controller module halfway into the system.

    Do not completely insert the controller module in the chassis until instructed to do so.

  3. Recable the system, as needed.

    If you removed the media converters (QSFPs or SFPs), remember to reinstall them if you are using fiber optic cables.

  4. If the power supplies were unplugged, plug them back in and reinstall the power cable retainers.

  5. Complete the installation of the controller module:

    1. Using the locking latches, firmly push the controller module into the chassis until it meets the midplane and is fully seated.

      The locking latches rise when the controller module is fully seated.

      Note Do not use excessive force when sliding the controller module into the chassis to avoid damaging the connectors.

      The controller module begins to boot as soon as it is fully seated in the chassis. Be prepared to interrupt the boot process.

    2. Fully seat the controller module in the chassis by rotating the locking latches upward, tilting them so that they clear the locking pins, gently push the controller all the way in, and then lower the locking latches into the locked position.

    3. If you have not already done so, reinstall the cable management device.

    4. Interrupt the normal boot process and boot to LOADER by pressing Ctrl-C.

      Note If your system stops at the boot menu, select the option to boot to LOADER.
  6. Reset the time and date on the controller:

    1. Check the date and time on the healthy controller with the show date command.

    2. At the LOADER prompt on the target controller, check the time and date.

    3. If necessary, modify the date with the set date mm/dd/yyyy command.

    4. If necessary, set the time, in GMT, using the set time hh:mm:ss command.

    5. Confirm the date and time on the target controller.

  7. At the LOADER prompt, enter bye to reinitialize the PCIe cards and other components and let the controller reboot.

  8. Return the controller to normal operation by giving back its storage: storage failover giveback -ofnode impaired_node_name

  9. If automatic giveback was disabled, reenable it: storage failover modify -node local -auto-giveback true

Step 5: Switch back aggregates in a two-node MetroCluster configuration

After you have completed the FRU replacement in a two-node MetroCluster configuration, you can perform the MetroCluster switchback operation. This returns the configuration to its normal operating state, with the sync-source storage virtual machines (SVMs) on the formerly impaired site now active and serving data from the local disk pools.

This task only applies to two-node MetroCluster configurations.

Steps
  1. Verify that all nodes are in the enabled state: metrocluster node show

    cluster_B::>  metrocluster node show
    
    DR                           Configuration  DR
    Group Cluster Node           State          Mirroring Mode
    ----- ------- -------------- -------------- --------- --------------------
    1     cluster_A
                  controller_A_1 configured     enabled   heal roots completed
          cluster_B
                  controller_B_1 configured     enabled   waiting for switchback recovery
    2 entries were displayed.
  2. Verify that resynchronization is complete on all SVMs: metrocluster vserver show

  3. Verify that any automatic LIF migrations being performed by the healing operations were completed successfully: metrocluster check lif show

  4. Perform the switchback by using the metrocluster switchback command from any node in the surviving cluster.

  5. Verify that the switchback operation has completed: metrocluster show

    The switchback operation is still running when a cluster is in the waiting-for-switchback state:

    cluster_B::> metrocluster show
    Cluster              Configuration State    Mode
    --------------------	------------------- 	---------
     Local: cluster_B configured       	switchover
    Remote: cluster_A configured       	waiting-for-switchback

    The switchback operation is complete when the clusters are in the normal state.:

    cluster_B::> metrocluster show
    Cluster              Configuration State    Mode
    --------------------	------------------- 	---------
     Local: cluster_B configured      		normal
    Remote: cluster_A configured      		normal

    If a switchback is taking a long time to finish, you can check on the status of in-progress baselines by using the metrocluster config-replication resync-status show command.

  6. Reestablish any SnapMirror or SnapVault configurations.

Step 6: Return the failed part to NetApp

Return the failed part to NetApp, as described in the RMA instructions shipped with the kit. See the Part Return and Replacements page for further information.