3UF5011-3AJ10-1模块备件

3UF5011-3AJ10-1

（2） CEX总线的大总限制是电气限制，可能会有进一步的限制
以确定特定单元的性能。
（3） 在接口CI868、CI871和CI873中仅使用一个端口（CH1）。
如果冗余控制器（PM8XX）与冗余通信一起使用
接口，确保完全冗余，支持在线升级
固件。
建议练习始终使用以下命令启动IPConfig会话：
在分配预期IP地址之前，执行“恢复出厂设置”命令。
这将删除以前存储的备用MAC和IP地址（如果有）。看见
49页冗余配置中的MAC和IP地址处理。
在Control Builder中设置主CPU的IP地址时
备份CPU必须关闭（断电）。否则，备份CPU
它会接管，你就会断开连接。
一次通电时，主处理器始终是连接到
标记为“上部”的RCU链路连接器。
I/O系统3节配置
158 3BSE036351-510 A
3.在备份CPU上设置CN1端口的IP地址。使用默认设置
（0.0.2.0添加到主CPU的地址），除非您的网络
管理员另有要求。请参阅IPConfig联机帮助。
4.开始您的800xA工作场所。
5.在Project Explorer硬件树中创建控制器的表示。
确保将PM861/PM864/PM865/PM891处理器单元定义为：
冗余的请参阅Control Builder联机帮助。
6.在Project Explorer中，将控制器的IP地址设置为
主CPU。请参阅Control Builder联机帮助。
7.打开辅助CPU。检查您是否与
控制器。
I/O系统
有几种将I/O系统连接到AC 800M控制器的方法：
•通过CI856进行S100输入/输出。
•通过ModuleBus的S800输入/输出单元。在运行期间支持热配置，
各级冗余、HART路由和事件序列（SOE）。
•通过CI854/CI854A和CI840/CI840A、PROFIBUS DP的S800输入/输出装置。
支持HART路由、各级冗余和热配置
在运行期间。
如果使用网络冗余，则主设备的CN2端口的IP地址
无法使用IPConfig设置处理器。必须在控制中设置此地址
建设者
如果使用网络冗余，还必须设置CN2的IP地址
使用IPConfig的备份处理器的端口。请参阅IPConfig联机帮助。
无需在Control Builder中设置备份CPU的IP地址。
备份CPU的IP地址、CN1和CN2端口将仅用于
主CPU和备份CPU之间的内部通信。当
备份CPU接管，它还接管定义的主IP地址
在控件生成器中。控制网络上的其他单位将永远不会注意到
切换。
3节I/O系统的配置
3BSE036351-510 A 159
•通过CI854/CI854A和CI801、PROFIBUS DP的S800输入/输出装置。支持
HART路由和运行期间的热配置。
•S900输入/输出装置可连接到PROFIBUS DP。
•ABB驱动装置可通过CI801连接到ModuleBus，也可通过
PM8xx上的Modulebus。一些驱动设备可以直接连接
连接到PROFIBUS或PROFINET IO。请参阅特定驱动器
有关更多信息，请参阅文档。
•通过CI862接口的Genius远程I/O（TRIO）
•ControlNet上的Satt I/O（19“Satt机架I/O、S200 I/O和S200L I/O）通过
CI865
•通过CI871的PROFINET IO
有关支持的I/O系统和单元的更多信息，请参阅I/O文档。
模块总线
AC 800M控制器中的模块总线（PM891除外）由一个
电气和一个光学单元。PM891仅由光学模块总线组成。
以下是ModuleBus的详细信息：
•电气模块总线（见160页图54）–1个集群（组），带有
多连接12个S800输入/输出单元。
•光学模块总线（见160页图54）–7个集群（组），带
连接的大7 x 12=84个S800输入/输出单元。
请注意，电气模块总线只能用于连接S800 I/O
当AC 800M以单CPU配置运行时。
PM851/PM851A仅限于一个光模块总线集群。
使用冗余将减少S800信道的大数量。每个
群集多可包含12个单个S800 I/O单元或6个冗余S800 I/O单元
单位。
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这提供了总共八个群集（组），大8 x 12=96 S800
I/O单元连接到具有单CPU配置的AC 800M控制器。
图54.电气和光学模块总线配置
多7
集群（组）
多12个I/O单元
PM8xx
TB820
TB820
TB820光学
地方的
模块总线
中央/远程
视力的
模块总线
与电有关的
模块总线
（大值为1
PM851集群）
3节I/O系统的配置
3BSE036351-510 A 161
在冗余CPU配置中，S800 I/O通过光纤连接
模块总线。每个CPU连接到每个集群上的一个TB840（请参见上的图55）
161页）。

3UF5011-3AJ10-1

3UF5011-3AJ10-1

(2) The maximum total limit on CEX-Bus is the electrical one, there might be further limitations due to performance for a particular unit. (3) Only one port (CH1) is used in the interfaces CI868, CI871 and CI873. If redundant controllers (PM8XX) are used along with redundant communication interfaces, it ensures full redundancy and supports the online upgrade of firmware. It is recommended to make a practice of always starting an IPConfig session with a “Restore factory settings” command before assigning the intended IP addresses. This will erase previously stored alternative MAC and IP addresses if any. See MAC and IP Address Handling in Redundant Configuration on page 49. When setting the IP address of the primary CPU in Control Builder, the backup CPU must be turned off (powered down). Otherwise the backup CPU will take over and you get disconnected. At the first power-up, the primary processor is always the one connected to the RCU Link connector marked “UPPER”. I/O Systems Section 3 Configuration 158 3BSE036351-510 A 3. Set the IP address of the CN1 port on the backup CPU. Use default settings (0.0.2.0 is added to the address of the primary CPU), unless your network administrator requires otherwise. See IPConfig online help. 4. Start your 800xA Workplace. 5. Create a representation of the controller in the Project Explorer hardware tree. Make sure the PM861/PM864/PM865/PM891 processor unit is defined as redundant. See Control Builder online help. 6. In Project Explorer, set the IP address of the controller to the IP address of the primary CPU. See Control Builder online help. 7. Switch on the secondary CPU. Check that you have communication with the controller. I/O Systems There are several methods of connecting I/O systems to the AC 800M Controller: • S100 I/O via CI856. • S800 I/O units via the ModuleBus. Support for hot configuration during run, redundancy on all levels, HART routing, and Sequence-of-Events (SOE). • S800 I/O units via CI854/CI854A and CI840/CI840A, PROFIBUS DP. Support for HART routing, redundancy on all levels, and hot configuration during run. If network redundancy is used, the IP address of the CN2 port of the primary processor cannot be set using IPConfig. This address must be set in Control Builder If network redundancy is used, you also have to set the IP address of the CN2 port of the backup processor using IPConfig. See IPConfig online help. There is no need to set IP address(es) for the backup CPU in Control Builder. The IP address of the backup CPU, CN1 and CN2 ports will only be used for internal communication between the primary and backup CPUs. When the backup CPU takes over, it also takes over the primary IP address that is defined in Control Builder. Other units on the control network will never notice the switchover. Section 3 Configuration I/O Systems 3BSE036351-510 A 159 • S800 I/O units via CI854/CI854A and CI801, PROFIBUS DP. Support for HART routing, and hot configuration during run. • S900 I/O units can be connected to PROFIBUS DP. • ABB Drives can be connected to the ModuleBus, via CI801 and also via Modulebus on the PM8xx. Some Drives equipment can be connected directly to PROFIBUS or PROFINET IO. Please refer to Drives-specific documentation for more information. • Genius remote I/O (TRIO) via the CI862 Interface • Satt I/O on ControlNet (19” Satt rack I/O, S200 I/O and S200L I/O) via the CI865 • PROFINET IO via CI871 For more information on supported I/O systems and units, see I/O documentation. ModuleBus The ModuleBus in the AC 800M controller, except PM891, consists of one electrical and one optical unit. The PM891 consists of optical ModuleBus only. The following are the details of the ModuleBus: • Electrical ModuleBus, (see Figure 54 on page 160) – 1 cluster (group), with a maximum of 12 S800 I/O units connected. • Optical ModuleBus (see Figure 54 on page 160) – 7 clusters (groups), with maximum 7 x 12 = 84 S800 I/O units connected. Note that the electrical ModuleBus can only be used for connection of S800 I/O when AC 800M is running in single CPU configuration. PM851/PM851A is restricted to one optical ModuleBus cluster. Use of redundancy will reduce the maximum number of S800 channels. Each cluster may contain up to 12 single S800 I/O units or up to 6 redundant S800 I/O units. I/O Systems Section 3 Configuration 160 3BSE036351-510 A This provides a total of eight clusters (groups), with a maximum 8 x 12 = 96 S800 I/O units connected to an AC 800M Controller with single CPU configuration. Figure 54. Electrical and Optical ModuleBus Configuration Maximum of 7 clusters (groups) Maximum of 12 x I/O units PM8xx TB820 TB820 TB820 Optical Local ModuleBus Central/Remote Optical ModuleBus Electrical ModuleBus (Maximum of 1 cluster for PM851) Section 3 Configuration I/O Systems 3BSE036351-510 A 161 In redundant CPU configuration, S800 I/O is connected through the optical ModuleBus. Each CPU is connected to one TB840 on each cluster (see Figure 55 on page 161). Figure 55. Optical ModuleBus connection in redundant CPU configuration Maximum of 7 clusters (groups) Maximum of 12 x I/O units 2 x TB840 2 x TB840 2 x TB840 Optical Local ModuleBuses Central/Remote Redundant CPUs Electrical ModuleBus cannot be used I/O Systems Section 3 Configuration 162 3BSE036351-510 A PROFIBUS DP A PROFIBUS DP segment, capable of providing up to 32 nodes, can be directly connected to a PROFIBUS DP Interface unit type CI854A/TP854. This segment can be further extended using repeater units. PROFIBUS PA can be connected to PROFIBUS DP via the PROFIBUS linking device LD 800P, see Appendix C, Recommended Components. For further details refer to PROFIBUS documentation, available at the PROFIBUS Internet site. It is possible to connect the following I/O systems to the PROFIBUS DP: • S800 I/O and/or S800L I/O via FCI – refer to S800 I/O documentation. • S900 I/O via FCI CI920 - refer to S900 I/O documentation. • S200 I/O and/or S200L I/O via Fieldbus Adapter 200-APB12 – refer to S200 I/O documentation. Restrictions apply for PROFIBUS DP. • Other I/O systems can also be connected to PROFIBUS DP. Refer to the relevant manufacturer’s documentation. For further information on the various I/O sy