AB Soft Mercury 3000Si manual Installation Instructions, Linear Encoders Mounting

Page 6

Installation Instructions

Linear Encoders - Mounting

1slide. Reference the preferred datum on the interface drawing for either end or center index orientation.

Depending on the mounting method, attach the scale to the

slide with adhesive. Refer to pg. 8 for details.Attach the scale to the base

Be sure the grating surface of the scale faces the sensor. Insure that there is no contact between these surfaces or damage may result.

CAUTION: observe precautions for handling elec- trostatic sensitive devices.

Route the sensor cables through your equipment to the Dual Axis SmartPrecision electronics module.

3

A) Remove the three cover screws and the top

Sensor 1

 

 

half of the connector housing. Do not pull on

 

 

 

the 25-pin D-sub connector or the circuit

 

 

board under the insulation layer.

 

 

B) Attach each sensor's 5 X 2 connector to the

 

 

mating 5 X 2 connector on the circuit board.

 

 

C) Route the sensor cables through their channels

 

 

in the center of the connector body and place

 

 

the cable's hex sleeves in the matching recesses.

 

 

Attach the top half of the connector housing

 

 

to the bottom half using the three cover screws.

 

 

 

 

Install the sensors on your mounting surfaces referencing the appropriate datum surface as shown on the interface drawing. Use 2 washers

2 per mounting screw.

Benching pins may be used to locate each sensor if the system mechanical tolerances are adequate. See data sheet for alignment tolerances, or keep mounting screws loose for sensor alignment if benching pins are not used.

Be sure the source power is off before connecting the SmartPrecision plug.

4 Connect the SmartPrecision electronics to the controller using the pinout diagram described on the interface drawing.

Insure proper system grounding. Refer to the proce- dure on pg 9.

Tighten the thumb screws.

Power up the system. The Power and Signal indica- tors for both sensors will illuminate.

Sensor 2

Page 4

Image 6
Contents Mercury 3000Si Dual Axis Averager Introduction Mercury family M10 of encoders Table Of Contents Mercury 3000Si Encoder System With Linear scaleWith Rotary scale Shown with Rotary scaleInstallation Instructions Linear Encoders MountingLinear Encoders Alignment Proper Alignment LEDRotary Encoders Mounting Rotary Encoders Alignment Confirm proper alignment over the full range of motionMounting the Scale Installation of Linear Scales Positioning the ScaleReference Section Epoxy and RTV Mounting Recommended for best accuracyRecommendations for Power Signal Wiring Customer Interface Cable RequirementsShield Termination Signal Description Serial Output SpecificationSignal Description IntroductionIndex Processing Optional SmartPrecision Software Installation Instructions Hardware RequirementsMicroE SS300cDI SmartPrecision Software Preliminary Configuration and Setup SmartPrecision Software Main ScreenOutput Configuration Assignment for Output M3000SiDAA ConfigurationConfigurations screen ChannelChannel 1 & 2 Calibration Settings Display Setting Dual Axis Software Display SettingsCalibration SmartPrecision Software Confirm Calibration screenCalibrate SmartPrecision Software System Specifications FunctionOperational Modes Standard Communication Mode TspiL Operational Modes Trigger Approach Timing Diagram Troubleshooting SolutionCleaning scales Contact MicroE Systems

Mercury 3000Si specifications

The AB Soft Mercury 3000Si is a leading-edge software suite specifically designed for managing and optimizing various business processes. This powerful platform is crafted to meet the demands of modern businesses, providing tools that enhance efficiency, streamline operations, and foster better decision-making.

One of the standout features of the Mercury 3000Si is its advanced data analytics capability. By harnessing sophisticated algorithms and machine learning technology, the platform enables users to gain valuable insights from their data. This function allows businesses to identify trends, forecast demand, and make data-centric decisions that can significantly impact their operations.

Another key characteristic of the Mercury 3000Si is its user-friendly interface. The software is designed with a modern aesthetic and intuitive navigation, making it accessible for users at all levels of technical proficiency. This emphasis on user experience minimizes the learning curve and facilitates a smoother integration into everyday business processes.

The platform also provides robust reporting tools that allow organizations to generate custom reports with ease. Users can select from a range of templates or create their own, making it simple to present data in a visually appealing format. These reporting capabilities enable businesses to track KPIs effectively and share actionable insights with stakeholders.

In terms of scalability, the Mercury 3000Si offers a modular architecture that accommodates businesses of all sizes. Whether a small startup or a large corporation, users can tailor the software to meet their specific needs by adding or removing components as required. This flexibility ensures that the platform remains relevant as organizations grow and evolve.

Security is another prime consideration in the design of the Mercury 3000Si. The platform employs cutting-edge encryption technologies and follows best practices to protect sensitive data. Regular updates and maintenance also ensure that users are safeguarded against emerging threats and vulnerabilities.

Furthermore, the Mercury 3000Si is optimized for cloud deployment, offering the benefits of accessibility and collaboration. With cloud integration, users can access the software remotely, facilitating real-time collaboration across teams and locations.

In conclusion, the AB Soft Mercury 3000Si is an exceptional software solution that combines advanced analytics, user-friendly design, scalable architecture, robust security features, and cloud capabilities. It is an invaluable asset for businesses striving for operational excellence and data-driven decision-making in an increasingly competitive landscape.