Dell PowerEdge MX7000 EMC OpenManage Enterprise-Modular Edition Version 1.20.1 - Page 27

The Firmware tab is displayed. 8. Select the Configure all devices to use following catalog check box, select the network share type and, click Catalog to open the Add Firmware Catalog window. 9. Enter a name for the catalog, select the catalog source, and click Finish to save the changes and return to the Chassis Deployment Wizard. 10. Click Next to view the Proxy tab and configure the proxy settings. OME-Modular uses the proxy settings to access the Dell EMC website for the latest catalogs. You can also enable the HTTPS proxy settings and proxy authentication. 11. Click Next to view the Group Definition tab. 12. Select Create Group to configure the chassis group settings. 13. Click Next to view the Summary tab. NOTE: After setting the time in the lead chassis, wait for the lead chassis time and the member chassis time to synchronize before performing any operation. The time configuration can be disruptive. Configuring chassis settings You can configure the following settings for a chassis: ● Power ● Network ● Network Services ● Local Access Configuration ● Location ● Quick Deploy Configure chassis power To configure the chassis power settings: 1. Click Devices > Chassis > View Details > Settings > Power. The Power configuration section is expanded. 2. Select Enable Power Cap to specify the maximum power consumption capacity for the chassis. The Power Cap limits the power consumption of the chassis. When the power cap is reached, the sleds are throttled based on their power priority. You can specify the capacity in Watts, BTU/h, or percentage. The Power Cap option is displayed only if the Enable Power Cap check box is selected. The recommended power cap is 0-32767 Watts or 0-100 %. If you change the power cap in BTU/h, the power cap in W also changes. MX7000 chassis supports power sources of 110 and 220 Volts. 3. In the Redundancy Configuration section, select the required redundancy policy. Power redundancy policies facilitate management of power consumption and power failure tolerance in the chassis. The available options are: ● No Redundancy-This policy distributes the enclosure power load across all PSUs. There are not any specific PSU population requirements for No Redundancy. The intent of the No Redundancy policy is to have the highest possible limit for power enablement of devices that are added to the enclosure. If there are single or multiple PSU failures, then the enclosure limits the performance to operate within the power capabilities of the remaining PSUs. ● Grid Redundancy-This policy distributes the enclosure power load across all PSUs. The six PSUs are organized into two groups: Grid A consists of PSUs 1, 2, 3, and Grid B consists of PSUs 4, 5, 6. It is recommended that the PSUs are populated in the following order: 1, 4, 2, 5, 3, 6, where an equal number of PSUs on each grid is optimized for Grid Redundancy. The grid with the largest PSU capacity determines the limit for power enablement of devices that are added to the enclosure. If there is a grid or PSU failure, then the enclosure power is distributed among the remaining PSUs with the intent that a single healthy grid continues to provide power to the system without degrading the performance. ● PSU Redundancy-This policy distributes the enclosure power load across all PSUs. There are no specific PSU population requirements for redundant PSUs. PSU redundancy is optimized for a population of six PSUs, and the enclosure limits the power enablement of devices to fit within five PSUs. If there is a single PSU failure, then the enclosure power is distributed among the remaining PSUs without degrading the performance. If there are less than six PSUs, then the enclosure limits the power enablement of devices to fit within all populated PSUs. If there is a single PSU failure, then the enclosure limits the performance to operate within the power capabilities of the remaining PSUs. Logging in to OME-Modular 27