What is the core functional differentiation between the DS200SLCCG1AEE and the DS215SLCCG1AZZ01B modules?

The DS200SLCCG1AEE is a high‑bandwidth communication and control interface designed for GE Mark VI/VIe distributed control systems, enabling real‑time network coordination using protocols like Base Ethernet, Modbus RTU/TCP, and ARCNET. In contrast, the DS215SLCCG1AZZ01B serves as a LAN communications card within the GE Mark V platform, optimized for local network traffic and protocol interfacing within that specific drive/control environment.

Which communication protocols and network layers are supported by the DS200SLCCG1AEE and DS215SLCCG1AZZ01B?

The DS200SLCCG1AEE supports multi‑protocol interfaces including Ethernet 10/100 Mbps, RS‑485, optional ARCNET, and industrial communication stacks such as Modbus RTU/TCP and GE’s proprietary turbine control communications. The DS215SLCCG1AZZ01B primarily supports the LAN standard framework used within Mark V systems, enabling network connectivity via IEEE‑compliant Ethernet and dedicated LAN interconnects.

How do the operational environments and thermal tolerances compare between the DS200SLCCG1AEE and DS215SLCCG1AZZ01B?

The DS200SLCCG1AEE is engineered to operate reliably from 0 °C to 60 °C while tolerating non‑operational extremes beyond those ranges, allowing wide‑range environmental deployment. The DS215SLCCG1AZZ01B typically exhibits an industrial operating range of approximately −40 °C to +70 °C, ensuring robust functional stability in harsher thermal conditions within Mark V installations.

In what system architectures are the DS200SLCCG1AEE and DS215SLCCG1AZZ01B predominantly used?

The DS200SLCCG1AEE is a cornerstone communication node in GE Mark VI/VIe turbine control architectures, synchronizing distributed I/O, HMIs, RTUs, and historian systems across gas, steam, and renewable energy applications. The DS215SLCCG1AZZ01B is intrinsic to the Mark V furnace/drive control ecosystem, facilitating LAN data exchange across control modules within that platform.

What are the power supply requirements and form‑factor considerations for each part?

The DS200SLCCG1AEE is specified for a nominal 24 V DC supply (18–30 V DC range), with compact mechanical packaging for racks or DIN configurations. The DS215SLCCG1AZZ01B similarly runs on a 24 V DC industrial supply and is constructed with surface mount technology and DIN‑rail mounting for integration into conventional industrial control cabinets.

How do redundancy and fault‑tolerant features manifest in the communications topology of these modules?

The DS200SLCCG1AEE supports redundant architectures—allowing hot‑swap capability and minimized system downtime in turbine control networks, with firmware‑level diagnostics to maintain high availability. The DS215SLCCG1AZZ01B, while focused on reliable LAN operations within the Mark V series, does not natively provide the same level of redundancy infrastructure but integrates with Mark V’s resilient control systems.

Why might engineers choose the DS200SLCCG1AEE over the DS215SLCCG1AZZ01B in modern industrial automation?

Engineers favor the DS200SLCCG1AEE when advanced interoperability, multiple protocol support, and real‑time deterministic networking are required across heterogeneous systems or distributed supervisory architectures. Conversely, the DS215SLCCG1AZZ01B is preferred where legacy Mark V configurations demand field‑proven LAN connectivity for existing control networks.

DS200SLCCG1AEE DS215SLCCG1AZZ01B

Name: DS200SLCCG1AEE DS215SLCCG1AZZ01B
Brand: General Electric
SKU: DS200SLCCG1A

LAN Communications Card，PC boards typically have multiple interface types,LAN communication board

In Stock

Ships by Tuesday, June 23

Fast Shipping Available

Product Information:

a LAN Communications Card manufactured and designed by General Electric
as part of the Mark V Series used in the GE Speedtronic Gas Turbine
Control systems. The SLCC features a 16- position alphanumeric display
(and display controller, U18) that connects to the programmer module.
The programmer module mounts on the SLCC and plugs into the
connector KPPL.The principal microprocessor on the SLCC is the LAN Control
Processor U1(LCP).The LCP software is stored in two replaceable EPROMs(U6 and U7)

Warranty Policy

We provide 1 year warranty for all remaining parts.
The warranty period is one year from the date of shipment, unless otherwise stated in the parts description. We guarantee that the project will not exhibit functional defects that may occur under normal operating conditions during the warranty period.

Return Notice

The warranty period is one year from the date of shipment, unless otherwise stated in the parts description. We guarantee that the project will not exhibit functional defects that may occur under normal operating conditions during the warranty period.
In the event of a defect, we will send new equipment, repair equipment or refund the purchase price based on our availability. You must contact us to obtain a return authorization and return the defective device to us within 14 days of reporting the defect.

Shiping Mode

Various transportation options are available in each country. Shipping methods and fees are clearly indicated on all quotations.Various transportation options are available in each country. Shipping methods and fees are clearly indicated on all quotations.

Parts Availability

Moore automated offers a wide range of components, products and services related to industrial automation. We have a large surplus of stocks and are also distributors of new products from a variety of quality manufacturers.

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Technical specifications for DS200SLCCG1AEE DS215SLCCG1AZZ01B

Manufacturer:

General Electric
Product Category:

Gas Turbine Control
Spare Part Number:

DS200SLCCG1A
Estimated shipping dimensions:

18.8x14.2x2cm
Weight:

0.24 kg
Tariff Code:

8537101190
Country of origin:

USA
Place of shipment:

Xiamen, Fujian, China
Operating Temperature::

0°C to 70°C
VLAN Support::

IEEE 802.1Q
Jumbo Frames::

Up to 9 KB
Power Consumption::

<5W
Flow Control::

IEEE 802.3x
Memory::

Onboard buffer memory
Stock:

40

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DS200SLCCG1AEE DS215SLCCG1AZZ01B

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What is the core functional differentiation between the DS200SLCCG1AEE and the DS215SLCCG1AZZ01B modules?

The DS200SLCCG1AEE is a high‑bandwidth communication and control interface designed for GE Mark VI/VIe distributed control systems, enabling real‑time network coordination using protocols like Base Ethernet, Modbus RTU/TCP, and ARCNET. In contrast, the DS215SLCCG1AZZ01B serves as a LAN communications card within the GE Mark V platform, optimized for local network traffic and protocol interfacing within that specific drive/control environment.
Which communication protocols and network layers are supported by the DS200SLCCG1AEE and DS215SLCCG1AZZ01B?

The DS200SLCCG1AEE supports multi‑protocol interfaces including Ethernet 10/100 Mbps, RS‑485, optional ARCNET, and industrial communication stacks such as Modbus RTU/TCP and GE’s proprietary turbine control communications. The DS215SLCCG1AZZ01B primarily supports the LAN standard framework used within Mark V systems, enabling network connectivity via IEEE‑compliant Ethernet and dedicated LAN interconnects.
How do the operational environments and thermal tolerances compare between the DS200SLCCG1AEE and DS215SLCCG1AZZ01B?

The DS200SLCCG1AEE is engineered to operate reliably from 0 °C to 60 °C while tolerating non‑operational extremes beyond those ranges, allowing wide‑range environmental deployment. The DS215SLCCG1AZZ01B typically exhibits an industrial operating range of approximately −40 °C to +70 °C, ensuring robust functional stability in harsher thermal conditions within Mark V installations.
In what system architectures are the DS200SLCCG1AEE and DS215SLCCG1AZZ01B predominantly used?

The DS200SLCCG1AEE is a cornerstone communication node in GE Mark VI/VIe turbine control architectures, synchronizing distributed I/O, HMIs, RTUs, and historian systems across gas, steam, and renewable energy applications. The DS215SLCCG1AZZ01B is intrinsic to the Mark V furnace/drive control ecosystem, facilitating LAN data exchange across control modules within that platform.
What are the power supply requirements and form‑factor considerations for each part?

The DS200SLCCG1AEE is specified for a nominal 24 V DC supply (18–30 V DC range), with compact mechanical packaging for racks or DIN configurations. The DS215SLCCG1AZZ01B similarly runs on a 24 V DC industrial supply and is constructed with surface mount technology and DIN‑rail mounting for integration into conventional industrial control cabinets.
How do redundancy and fault‑tolerant features manifest in the communications topology of these modules?

The DS200SLCCG1AEE supports redundant architectures—allowing hot‑swap capability and minimized system downtime in turbine control networks, with firmware‑level diagnostics to maintain high availability. The DS215SLCCG1AZZ01B, while focused on reliable LAN operations within the Mark V series, does not natively provide the same level of redundancy infrastructure but integrates with Mark V’s resilient control systems.
Why might engineers choose the DS200SLCCG1AEE over the DS215SLCCG1AZZ01B in modern industrial automation?

Engineers favor the DS200SLCCG1AEE when advanced interoperability, multiple protocol support, and real‑time deterministic networking are required across heterogeneous systems or distributed supervisory architectures. Conversely, the DS215SLCCG1AZZ01B is preferred where legacy Mark V configurations demand field‑proven LAN connectivity for existing control networks.

DS200SLCCG1AEE DS215SLCCG1AZZ01B

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