4 BUTTON GLASS FASCIA. PW
5084F-PW fascia image
Angled image of 5084F-30 4 GANG GLASS FASCIA CREAM
Angled image of 5084F-60 C-Bus Key Input Fascia Black
Angled image of 5084F-GF C-Bus 4 key input glass facia
5084F-J0 fascia image
4 BUTTON GLASS FASCIA. PW
5084F-PW fascia image
Angled image of 5084F-30 4 GANG GLASS FASCIA CREAM
Angled image of 5084F-60 C-Bus Key Input Fascia Black
Angled image of 5084F-GF C-Bus 4 key input glass facia
5084F-J0 fascia image

Glass Fascia, 4 Gang, Saturn Series, Rectangular

Catalogue Number: 5084F
4 BUTTON GLASS FASCIA. PW
5084F-PW fascia image
Angled image of 5084F-30 4 GANG GLASS FASCIA CREAM
Angled image of 5084F-60 C-Bus Key Input Fascia Black
Angled image of 5084F-GF C-Bus 4 key input glass facia
5084F-J0 fascia image
4 BUTTON GLASS FASCIA. PW
5084F-PW fascia image
Angled image of 5084F-30 4 GANG GLASS FASCIA CREAM
Angled image of 5084F-60 C-Bus Key Input Fascia Black
Angled image of 5084F-GF C-Bus 4 key input glass facia
5084F-J0 fascia image
Retail
$121.39
RRP (Inc. GST)
Colour Pure White (PW)
  • Pure White 1 PCE
  • Cream 1 PCE
  • Black 1 PCE
  • Glass Finish 1 PCE
  • Stainless Steel 1 PCE

Specifications

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Range of product
  • Australian Series
  • C-Bus
  • Saturn Series
    • Range
      C-Bus
      Product brand
      Clipsal
      Number of gangs
      4 gangs
      Product destination
      switch
      Material
      glass
      Control type
      button
      Marking
      without marking
      Mounting position
      vertical
      Fixing center
      84 mm
      Length
      116 mm
      Width
      76 mm
      Depth
      12 mm
      Package 1 Weight
      0.1 kg
      Package 1 Height
      12 mm
      Package 1 width
      76 mm
      Package 1 Length
      116 mm
      EU RoHS Directive
      Compliant
      Mercury free
      Yes
      RoHS exemption information
      Yes
      China RoHS Regulation
      Product out of China RoHS scope. Substance declaration for your information
      Circularity Profile
      ENVEOLI121001EN

      Documents & downloads

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      Filter items
      • All

      • Product Brochures

      • Technical Data Catalogues

      • Technical Leaflet

      • Installation Instruction

      • End of Life Manual

      • Corporate Marketing

      Frequently Asked Questions

      hide show

      What is the part number for the Fascia only on a Cbus Saturn 4 gang plate ?

      The part number will be 5084F- and then colour reference eg 5084F-PW for Pure White Fascia

      What is the facia in black to suit 5084NL

       Part code is 5084F-60

      What is the part number for black cover to suit 5084NL?

      The part number for black  cover only to suit 5084NL is 5084F-60.

       

      SSH server running after restored configuration of InfraStruXure Central

      Issue:

      SSH server running after restored configuration of InfraStruXure Central

      Product Line:

      InfraStruxure Central

      Environment:

      InfraStruxure Central
      StruxureWare Central
      StruxureWare Data Center Expert.

      Cause:

      If SSH is turned on, it will be turned off after the configuration is restored as this is the default setting.

      Resolution:

      This issue was found in ISXC 5.1.1 and the only current resolution is to manually reconfigure SSH settings.

      The Replace Battery Date on my new SMT series Smart-UPS is incorrect.

      Issue:

      The Replace Battery Date indicated on the LCD screen of my new SMT series Smart-UPS is incorrect.


      Product Line:

      Smart-UPS

      Environment:

      Models beginning with SMT , All Serial Numbers

      Cause:

      The "Replace Battery by" field indicates an estimated date when the UPS Battery may need to be replaced. This field is dynamic  and changes depending on the operating environment of the UPS. It is not a definitive indicator of a bad battery, but it does give the customer some guidance of when to expect a need for replacement.

      This field defaults to 4.5 years from the time of the last battery replacement. Occasionally you may find that on a new SMT series UPS the "Replace Battery By" date indicated on the LCD is far into the future, and therefore incorrect. 


      Resolution:

      To correct this issue select “Reset to Factory Defaults” from the “Configuration” menu of the LCD screen on the front of the UPS
      You will need to wait approximately 30 seconds until this process complete. The LCD  will indicate "Resetting to Fact Defaults" during this process.
      Upon completion, the UPS will start the new unit install wizard on the LCD screen and prompt you to set "Language", "Local Power Quality", "Menu Type", and "Audible Alarms".
      Once you have made your selections, manually select “Install New Battery” from the configuration menu on the LCD.
      This UPS will now properly calculate the Replace Battery Date (which will initially be  4.5 years in the future).
       

      Power Monitoring Expert 9.0 - upgrade fails at 'Verify Database' on ION_Network database - 'duplicate key was found for the object name 'dbo.Translator'

      Issue
      When upgrading to PME 9.0 from an earlier PME version, the 'Verify Database' step fails on the ION_Network database upgrade due to duplicate entries in the Translator table. You will see an error in the log file something like this:

      Error SQL72014: .Net SqlClient Data Provider: Msg 1505, Level 16, State 1, Line 1 The CREATE UNIQUE INDEX statement terminated because a duplicate key was found for the object name 'dbo.Translator' and the index name 'AK_Translator_Name'. The duplicate key value is (BCPM).
      Error SQL72045: Script execution error.  The executed script:
      ALTER TABLE [dbo].[Translator]
          ADD CONSTRAINT [AK_Translator_Name] UNIQUE NONCLUSTERED ([Name] ASC);


      Error SQL72014: .Net SqlClient Data Provider: Msg 1750, Level 16, State 1, Line 1 Could not create constraint or index. See previous errors.
      Error SQL72045: Script execution error.  The executed script:
      ALTER TABLE [dbo].[Translator]
          ADD CONSTRAINT [AK_Translator_Name] UNIQUE NONCLUSTERED ([Name] ASC);


      Product Line
      Power Monitoring Expert 9.0

      Environment
      Upgrading to Power Monitoring Expert 9.0 from PME 8.2 or earlier, whether an in-place upgrade, a CM tool Side by Side upgrade or a manual Side by Side upgrade

      Cause
      As of PME 9.0, a uniqueness constraint was imposed on the Name column in the Translator table in ION_Network. In some older ION_Network databases, it is possible to have duplicate entries in the Name column, usually for the BCPM, CM4000, MICROLOGIC or PM800 device types. During the upgrade to PME 9.0, imposing the uniqueness constraint fails due to the duplicate Name entries.

      Resolution

      *Warning: Irreparable database damage can occur. This procedure should only be performed by users familiar with SQL Server Management Studio. Databases should be backed up prior to performing this procedure.*​

      Method 1: Requires you to analyze the ION_Network database prior to the upgrade
      Prior to the upgrade, check the Translator table in the ION_Network database for duplicates by running the following query:

      USE ION_Network
      SELECT * FROM Translator
      ORDER BY Name


      If duplicates exist, run the attached .sql called 'clean_up_Translator_table.sql'.
      If this is done prior to upgrading to PME 9.0, you will not encounter this problem.

      Method 2: Assumes you have run the PME 9.0 Installer to upgrade from older PME versions and the Installer stops on 'Verify Database'.
      To correct this problem it is necessary to correct the Translator table. To do this, open SQL Server Management Studio (SSMS) and run the attached .sql called 'clean_up_Translator_table.sql'.
      It is also necessary to drop the WindowsTimeZoneId column in the SRC_Timezone table in the ION_Network database. This can be done within SSMS:
       
      1. Start SSMS
      2. Expand 'Databases', then the ION_Network database
      3. Expand 'Tables' and find the SRC_Timezone table
      4. Expand 'Columns', right click on the WindowsTimeZoneId column and choose 'Delete' from the popup menu

      Once this is done, if the Installer has been left running, click on 'Retry All Steps' to retry the upgrade and it will succeed.

      Important: If you do not delete the WindowsTimeZoneId column as described above, prior to retrying the upgrade, and only clean up the Translator table, you will see this error:

      Warning SQL72013: The following SqlCmd variables are not defined in the target scripts: ReferenceDataFilesPath.
      Error SQL72014: .Net SqlClient Data Provider: Msg 5074, Level 16, State 1, Line 39 The column 'WindowsTimeZoneId' is dependent on column 'RegistryKey'.
      Error SQL72045: Script execution error.
      ...
      Error SQL72014: .Net SqlClient Data Provider: Msg 4922, Level 16, State 9, Line 39 ALTER TABLE ALTER COLUMN RegistryKey failed because one or more objects access this column.
      Error SQL72045: Script execution error.  The executed script:
      DECLARE @CurrentSchemaVersion AS INT;


      To recover, simply use SSMS to delete the column, and then 'Retry All Steps' again.





       

      Wiring of RS485 Communications Networks

      Issue
      This document attempts to explain correct methods of wiring RS485 communication networks in industrial environments based on various application notes and technical articles.

      Environment
       
      RS485 Serial Modbus Communications

      Resolution
       
      1. RS-485 (EIA/TIA-485) Differential Data Transmission System Basics
       
      The RS-485 standard was developed jointly by two trade associations: the Electronic Industries Association (EIA) and the Telecommunications Industry Association (TIA). The original prefix "RS" stands for Recommended Standard and has been officially replaced with "EIA/TIA" to help identify the origin of its standards.
       

       

        RS-485 Standard Specifications
      Mode of operation
      Differential
      Allowed no. of Tx and Rx
      32 Tx 32 Rx
      Maximum cable length
      4000ft length
      Maximum data rate
      10Mbps
      Minimum driver output range
      ±1.5V
      Maximum driver output range
      ±5V
      Minimum drive capability
      ±55mA
      Maximum driver short-circuit current
      250mA
      Tx load impedance
      54
      Rx input sensitivity
      ±200mV
      Maximum Rx input resistance
      12k
      Rx input voltage range
      -7V to +12V
      Rx logic high
      >200mV
      Rx logic low
      <200mV
      Max common mode voltage
      -7V to +12V

       
      Full duplex implementation requires 4 wires. This may be necessary for some applications involving legacy devices. In half-duplex implementation 2 wires are used this is the recommended configuration for most Schneider Electric PMC devices.
        •  
      All products manufactured by Schneider Electric PMC support half-duplex, 2 wire configuration. The 4 wire interface is usually implemented in order to avoid creating a T (tee) or star connections or to support full duplex connections.
       
      A twisted pair type of cable should be used in order to reduce radiated emissions and improve immunity of the communications system to any external electromagnetic interference.
       
      The National Electrical Code and all applicable local regulations must be followed when installing the communications wiring.
       
      Cable examples:
        • -Belden 9841 or Alpha 6412 or equivalent cable may be used for applications under 300V that are indoors or outdoors in conduit above grade.
                 
        • -Belden 3074F or equivalent cable may be used for applications greater than 300V which are indoors or outdoors in conduit above grade.
       
      In all devices the RS485 ports are opto-isolated from the internal device electronics. All devices with RS485 port have a shield terminal, which may be connected to the chassis ground (e.g. on 7X50, 880, 8600) or to the isolated reference of the RS485 port (i.e. no connection to the chassis ground as in 6200, 6300, 6100)
        •  
        •  
      2. Network Configuration
       
      2.1 Topology
      Several types of network topologies are possible, but the daisy-chain bus configuration is the most efficient. Typically, one of the units is the master controlling the network traffic and prevents multiple drivers from being active at the same time (bus contention). A shielded twisted pair cable is the physical medium. The cable impedance should be within 100-120? range. In the Backbone with Studs technology, no studs should be left unconnected at the device end. Otherwise, such a stud will act as an antenna and introduce a significant amount of noise on the RS485 bus, to such a point that comms may become impossible. This is actually a fairly common source of problems.
       

       
       
      The longer the cable, the lower the data rate:
       
       
       
       
      2.2 Termination
      Termination resistors that match the cable's characteristic impedance are essential for minimizing reflections and consequently communication error rates and electromagnetic emissions. For common RS-485 cables (a twisted pair of 24AWG wires), this means a 100-120 resistor at both ends . Termination resistors should be used especially with long cable length to ensure data integrity. Note that, on very long cable length, adding termination resistors can sometime cause an additional drop of voltage that will cause a loss of communication on the devices that are furthest from the master. In this case, adding a repeater or removing some termination resistors can restore comms.
      2.3 Fails-Safe Biasing
       
      Open bus condition:
       
        • When a node is disconnected from the bus, the state of the bus, as seen by the  receiver, is undetermined and may result in random output from the receiver.  A weak failsafe biasing is recommended to ensure that the receiver does not enter undetermined state under open bus conditions.
           
      Idle bus condition:
       
        • When no drivers are active on a bus with termination resistors, those resistors will decrease the differential bus voltage to zero, which according to the RS485 standard, is an undefined bus condition. Biasing resistors should be used in order to generate a valid bus logic state under idle-bus conditions. Biasing resistors are only needed at one node (usually the master), hence configuration switches must be used if the biasing resistors are incorporated into every node. Only one device on the bus should be providing the biasing. The biasing resistors may be external or internal to the device. Some products e.g.8800, 7X50 have internal resistors which may be connected with internal switches to provide biasing of the bus.  The Com 32 and Com 128 have permanently connected biasing resistors.
           
      2.4 Unit Load (U.L.)
       
        • A one RS485 transceiver represent a load of 1U.L. The RS485 standard specifies the bus loading as 32 U.L.

       
      2.5 Shielding and Grounding
       
      The RS485 interface standard does not specify a ground wire, but such wire is needed to provide a return path for common mode currents and consequently reduce emissions. It may be possible to operate the RS485 loop without a ground wire, but such systems may radiate high levels of EMI.
                 
      A shield limits coupling of external interference and noise onto the bus. Generally the shield should be connected to the chassis ground (installation ground) at one end of the cable. In case of ground potential differences between nodes (common in industrial locations) this arrangement prevents the flow of DC ground loop currents in the shield. Ground loop currents flowing in the shield will induce noise in the communications cable. A capacitor or an RC network may be used between the other end and ground.
       

       
      The RS485 nodes can tolerate from -7V to +12V  of common mode voltage. When this voltage is exceeded the nodes are no longer guaranteed to function and may even be damaged.
      Due to significant differences in ground potentials that may and will be present between nodes in industrial locations, ground should not be used as a reference. In installations where ground is used as return path 100-120 resistors may be used to limit the ground currents flowing due to ground potential differences between devices. 
      The figure below illustrates the grounding concepts.
       
       


      Connection Example: 6300 meter, terminated daisy chain bus.
       
      The shield terminal is not connected to chassis ground of the meter. Installer must ensure low impedance connection to the system ground at one end of the cable. The 4 wire port on the 6300 is intended to help the installer avoid making T (or stub) connections.  Note the use of termination resistors RT.
       

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      Example: third party devices:                       
       
       


      Examples of improper networks Do NOT do this:
       
      Unterminated cable:

      Incorrect location of termination resistor:

       
      Multiple cables in a star configuration

       
      Backbone cable with long stubs:


      Please find a PDF copy of this document here:

      16798.pdf