Emerson Torque Arm Assembly Instructions, Mounting Instructions, Series 3000 Torque Arm Kits

Page 11

Torque Arm Assembly Instructions

Mounting Instructions

1.  For Series 3000, mount the torque arm as shown in Figure 5 to side of the reducer where the driven shaft enters.  Apply Loctite* 432 or equal to the threads of each bolt before assembly.

2.  Connect the reducer to the driven shaft.

3.  Attach torque arm to the mounting plate or attachment point. 4.  Tighten the cap screws to the recommended torque.

Series 3000 Torque Arm Kits

Table 1

OtN Frame

Kit Part ID#

31

ROC100KT001

32

ROC200KT001

 

 

33

ROC300KT001

34

ROC400KT001

35

ROC500KT001

 

 

36

ROC600KT001

37

ROC700KT001

 

 

38

ROC800KT001

Table 2

Fastener Size

Torque ( Ft. Lbs)

 

 

 

 

 

 

 

 

 

 

M10

49

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

M12

87

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

M16

220

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

M20

430

 

 

 

 

 

 

 

 

 

 

 

 

 

90°

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Table 3

OtN Frame(s)

Kit Hardware

 

 

31 and 32

Screws (4)

 

Roll Pin (1)

 

 

 

33, 34, 35

Screws (3)

 

Roll Pin (1)

 

 

 

36 and 37

Screws (4)

 

Roll Pin (1)

 

 

 

38

Screws ( 8 )

 

Roll Pin ( 2 )

 

 

 

180°

Anchoring of the

Torque Arm

(Top View)

270°

Figure 5

* The following trade names, trademarks and/or registered trademarks are used in this material by Emerson Power Transmission Corporation are NOT owned or controlled by Emerson Power Transmission Corporation and are believed to be owned by the following parties: LOCTITE: Henkel Corporation. Emerson Power Transmission Corporation cannot and does not represent or warrant the accuracy of this information.

11

Image 11
Contents Emerson Industrial Automation Installation InstructionsMaintenance 9020E Revised JanuaryAcceptable Mineral Oil Lubricants LubricantsStandard Synthetic Gear Oil Non Food Grade Standard Synthetic Gear Oil Food GradeQuarts Plug Location and Oil VolumeGearbox Mounting Positions OtN Shaft Mount Reducer Installation Clearance Mounting Configuration with Bushing Outboard of LoadEnd cap Minimum Shaft Minimum Key Mounting Connection Gear Length FrameMax Bolt Minimum Shaft KeyGear Clearance Mounting Connection Frame Length Bolt Minimum Shaft Minimum Key Mounting Connection Gear Taper Bushing Selection Dismounting of the Reducer from driven shaft Finished Bore MountingMounting Of Reducer with Finished Bore Shaft OtN Frame Kit Part ID# Torque Arm Assembly InstructionsMounting Instructions Series 3000 Torque Arm KitsOtN Series 3000 Gearmotors and Reducer TWO Stage OtN SeriesBearings Oil Seals Parts List Two Stage Frames 31Common Replacement Parts Item # Description Qty Per FrameOtN 32-35 Three Stages Quantity Per Unit Three Stage OtN SeriesBore plug utilized Parts List Three Stage Frame 32 throughItem # Description Frame SizeOtN 36-38 Three Stages Quantity Per Unit Bearings Oil Seals Top Cover gasket Parts List Three Stage Frame 36 throughGear Motor Bearings Seal inches Frame Face Input Parts ListOtN 31 38 Two and Three Stage Quantity Per Unit Description Of Part 320TC/360TC Face Coupling Input Parts ListOtN 36 38 Three Stage Quantity Per Unit AP Input Shaft Parts List Reduction Gear Motor Bearing Seal inches Gear Motor Input Parts ListBearings and Seals Double Reduction Triple Reduction 36, 37Description Qty Integral Motor Parts ListFrames 180T, 210T, 250T, A280T Frames 56, 140T
Related manuals
Manual 88 pages 63.05 Kb Manual 60 pages 24.1 Kb Manual 88 pages 36.41 Kb Manual 32 pages 13.16 Kb Manual 76 pages 17.32 Kb Manual 184 pages 52.9 Kb

3000 specifications

The Emerson 3000 is a cutting-edge control system designed to enhance the efficiency, reliability, and precision of industrial operations. Employed across various sectors such as oil and gas, pharmaceutical, food and beverage, and power generation, the Emerson 3000 has gained recognition for its robustness and versatility.

One of the main features of the Emerson 3000 is its advanced process control capability. With integrated control algorithms, it can optimize complex processes in real-time, resulting in significant improvements in production rates and reduced operational costs. The system's predictive analytics capabilities enable operators to anticipate equipment failures and maintenance needs, allowing for proactive management and minimizing downtime.

The Emerson 3000 features a modular architecture, providing flexibility for scaling and customization. Operators can easily tailor the system to fit specific application needs, whether it requires additional control loops or integration with other systems. This adaptability is particularly beneficial for facilities planning for future expansions or modifications.

Another technology highlight of the Emerson 3000 is its seamless integration with the latest Internet of Things (IoT) advancements. The system is designed to communicate effectively with a variety of smart devices and sensors, harnessing data to create insightful analytics that drive operational excellence. This connectivity empowers businesses to leverage big data for improved decision-making and increased agility.

Additionally, the Emerson 3000 incorporates state-of-the-art cybersecurity measures to safeguard critical data and operations. With built-in security protocols and regular updates, the system protects against emerging cyber threats, ensuring the integrity of the control network.

User experience is also a focal point of the Emerson 3000. The intuitive graphical user interface presents complex data in a user-friendly format, making it easier for operators to monitor system performance and respond to alerts quickly. This ease of use contributes to enhanced safety and operational efficiency.

In summary, the Emerson 3000 represents a fusion of advanced process control, modular design, IoT connectivity, robust cybersecurity, and user-centric interface, making it an ideal choice for industries seeking to enhance their operational performance while adapting to ever-evolving technological landscapes.