Schneider Electric ACRC500, ACRC502, ACRC501 manual Local access to the control console

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Option 43 = 01 04 31 41 50 43

where

the first byte (01) is the code

the second byte (04) is the length

the remaining bytes (31 41 50 43) are the Schneider Electric cookie

See your DHCP server documentation to add code to the Vendor Specific Information option.

To change the control console DHCP Cookie Is setting, use the Advanced option in the TCP/IP menu. See “Remote access to the control console” on page 33.

To disable the requirement that a DHCP offer include the Schneider Electric cookie, use the DHCP Cookie Is setting in the control console:

Network > TCP/IP > Boot Mode > DHCP only > Advanced > DHCP Cookie Is.

Local access to the control console

You can use a computer connected to the serial port on the main board holding the Network Management Card to access the control console.

1.Select a serial port at the local computer, and disable any service that uses that port.

2.Use the configuration cable to connect the selected port to the serial port on the main board holding the Network Management Card. Use either 940-0103, the 6-ft (1.8-m) cable that came with your UPS, or AP9804 (990-1524), the 15-ft (4.6-m) cable available from Schneider Electric.

3.Run a terminal program (such as HyperTerminal) and configure the selected port for 9600 or 19200 bps, 8 data bits, no parity, 1 stop bit, and no flow control. Save the changes.

4.Press ENTER to display the User Name prompt.

5.Use apc for the user name and password.

See “Control console” on page 34 to finish the configuration.

Remote access to the control console

From any computer on the same subnet as the Network Management Card, you can use ARP and Ping to assign an IP address to a Network Management Card, and then use Telnet to access the control console of that Network Management Card and configure the needed TCP/IP settings.

NOTE: After the IP address of the Network Management Card is configured, you can use Telnet without first using ARP and Ping to access that Network Management Card.

1.Use the MAC address for the Network Management Card in the ARP command to define the IP address. For example, to define an IP address of 156.205.14.141 for a Network Management Card that has a MAC address of 00 c0 b7 63 9f 67, use one of the following commands:

Windows command format:

arp -s 156.205.14.141 00-c0-b7-63-9f-67

– LINUX command format:

arp -s 156.205.14.141 00:c0:b7:63:9f:67

NOTE: The MAC address is available on the display interface at:

Path: Main > Configure Network or look at the label on the back of the Network Management Card for the MAC address.

2.Use Ping with a size of 113 bytes to assign the IP address defined by the ARP command. For the IP address defined in step 1, use one of the following Ping commands:

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Contents 990-3237B-001 Publication Date November Operation and Maintenance ManualSchneider Electric IT Corporation Legal Disclaimer Table of Contents Network Management Card Troubleshooting Page General Information Important Safety InformationHazard of Electric SHOCK, EXPLOSION, or ARC Flash Safety Notices During OperationStatic Electricity Hazard Ensure that ChecklistsInitial inspection checklist CommissioningElectrical Hazard Electrical inspection checklistPiping Installation Mechanical inspection checklistWhile the equipment is operating, ensure that User interface inspection checklistStart-up inspection checklist Final inspection checklistOperation Display InterfaceDescription Function Navigating the main menu Using the DisplayScrolling status screens Main menu screensUsing the Path statement Path Main Set Password Change PasswordsNavigating sub-menus Path Main On/Standby Password entryPath Main Operation Limit Access Start the cooling unitStandby Option Stop the cooling unitGeneral Configuration Cooling unit configurationPath Main Configure Unit General View the state of input and output contacts Path Main Configure Unit Discrete I/OPath Main Configure Unit Discrete I/O Normal State ContactsCooling Group Configuration Configure the cooling groupPath Main Configure Group Path Main Set Identification Configure ModbusPath Main Configure Modbus Identify the cooling unitPath Main Set Group Setpoints How the Cool mode worksControl the Environment SetpointsPath Main Set Group PIDs PID settingsLoop Behavior PID Tuning Correction Tune the PID loopControl Method Proportional Integral Derivative Service intervals Run hoursThresholds Date & time Display SettingsPassword & timeout Adjust displayPath Main Menu Set Display Units Display unitsNetwork Configuration Configure the networkPath Main Configure Network View Status Readings Cooling unit statusPath Main View Unit Status Path Main About InRow RC Cooling group statusAbout the cooling unit Path Main View Group StatusPath Main View Event Log Event LogView event log Clear event logAlarm messages and suggested actions Respond to AlarmsView active alarms Clear active alarmsThreshlds screen Configure Unit General Role Override Auto and that coolingAlarm Message Severity Action Required Network Management Card Quick ConfigurationTCP/IP configuration methods Schneider Electric Device IP Configuration WizardIni file utility Bootp & Dhcp configuration Local access to the control console Remote access to the control consoleNetwork TCP/IP Boot Mode Dhcp only Advanced Dhcp Cookie Is Choose Network from the Control Console menu Control consoleAccess a Configured Network Management Card Web interfaceTelnet and SSH Modbus Simple Network Management Protocol SnmpInRow RC Operation and Maintenance Manual Recover From a Lost Password Environment MaintenanceMonthly Preventive Maintenance CleanlinessElectrical MechanicalFunctional Semi-Annual Preventive MaintenanceProblem Possible Cause Corrective Action TroubleshootingProblem Possible Cause Corrective Action Page Page Worldwide Customer Support

ACRC501, ACRC502, ACRC500 specifications

Schneider Electric, a global leader in energy management and automation, has introduced its sophisticated line of edge computing solutions, namely the ACRC500, ACRC501, and ACRC502. These models are designed specifically to meet the increasing demand for efficient and reliable edge computing environments across various industries.

The ACRC500 serves as a compact and versatile solution that caters to small to medium-sized applications. It is engineered to optimize performance by utilizing advanced thermal management technologies. With a scalable architecture, the ACRC500 can easily be adapted for diverse workloads, making it ideal for facilities requiring quick deployment and efficient operation.

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