Andrew ES76PK-1 Tensioning Step, 1b A-325 Tensioning For bolts over four diameters

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A-325 Tensioning

Step 1

Step 2

Step 3

Step 4

Step 5

Step 6

During the installation process, there are several references to the A-325 hardware ten- sioning procedure. The A-325 hardware must be properly tensioned to avoid slippage between bolted surfaces under high loads. Slippage can cause the corresponding assembly to move, causing antenna misalignment. When designated, the A-325 hard- ware should be tightened according to the following tensioning procedure.

NOTE: Tensioned bolts are for final connections only and should not be loosened for reuse.

Lubricate the bolt threads with the provided stick wax to reduce friction.

Insert the bolt, and add a flat washer—if required. Do not allow wax under the flat washer.

Add the nut, and finger tighten.

After the connections are complete, tighten the bolts until the surfaces are joined and the nuts are snug (for example, full effort of a person using an ordinary spud wrench). Do not proceed with Steps 5 and 6, unless the connection is final and is not intended to be loosened again.

Note: If the bolts are loosened after Steps 5 and 6, discard and replace with new hard- ware.

Using a felt-tip marker, mark the nuts and the ends of the bolts with a straight line as shown in Figure 2-1a and Figure 2-1b.

Tighten the nuts further with an extra long wrench until the nuts are moved 1/3 turn (120 degrees) as shown in Figure 2-1a for bolt lengths less than four diameters and 1/2 turn (180 degrees) as shown in Figure 2-1b for bolt lengths over four diameters.

Use Felt Marker

Before After

Tensioning Tensioning

Figure 2-1a: A-325 Tensioning Procedure For bolts less than 4 diameters

Use Felt Marker

Before After

Tensioning Tensioning

Figure 2-1b: A-325 Tensioning For bolts over four diameters

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Installation Procedures

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Contents Meter ESA Table of Contents Introduction Meter Earth Station AntennaProprietary Data Information and Assistance Technical Customer Service CenterHow to Use This Manual Overview ContentGetting Started OverviewTool Size Quantity Recommended ToolsGetting Started Returning Equipment Step Overview Foundation Preparation Installation Procedures1b A-325 Tensioning For bolts over four diameters Tensioning StepPedestal Ground Mount Assembly Installation Step Step Step Azimuth Jack Arm Installation Azimuth Jackscrew Assembly Step AZ Jack Pin 302383 4 Washer, 9997-188 8x1.0 Bolt Lockwasher Elevation Jackscrew Assembly Step Reflector Backstructure Assembly Step Step Step Step Typical 4 Places Then panel 3 and panel 4, and so on Step Theodolite Reflector AlignmentRib Panel Skin Refer to Figure Step Installation Procedures Installation Procedures Step Reflector Alignment Installation Procedures Installation Procedures Reflector to Ground Mount Assembly Step View A-A Subreflector Installation StepSubreflector Strut Support 300089 4 Places Adjustment Hardware, 3 Places Part Subreflector Centering Step Focusing Operation Overview Acquiring a SatelliteStep Polarization at 45 degrees from Optimum Setting Maximizing Odd Transponders Subreflector Adjustment Survival Struts Preventive Maintenance Overview General Cleaning Electrical PartsPreventive Maintenance Antenna Preventive Maintenance Drive System Voltage Current Checks Step Step Preventive Maintenance Jackscrews/Motors Gear Motor/Housing Fill Drain Requirements Lubrication Chart Preventive Maintenance

ES76PK-1 specifications

The Andrew ES76PK-1 is a robust and highly efficient satellite communication antenna designed for both commercial and military applications. Its innovative design and advanced features make it an exceptional choice for high-performance connectivity.

One of the standout characteristics of the ES76PK-1 is its impressive gain. With a gain of approximately 76 dBi across a wide range of frequencies, it ensures optimal signal reception and transmission even in challenging environments. This high gain makes it ideal for applications requiring reliable long-distance communication, such as remote site operations or disaster recovery efforts.

The construction of the ES76PK-1 also prioritizes durability and resilience. Built with sturdy materials, this antenna is resistant to harsh weather conditions, including high winds, rain, and extreme temperatures. Its lightweight yet robust design allows for easier installation and maintenance, making it suitable for both fixed and mobile setups.

In terms of technology, the Andrew ES76PK-1 leverages advanced polarization techniques, which enhance its ability to transmit and receive signals effectively. This polarization capability ensures minimal signal degradation and interference, providing users with consistent and high-quality communication links. Furthermore, the antenna supports multiple frequency bands, thus offering flexibility in deployment and compatibility with various satellite systems.

The antenna's design incorporates a high level of precision engineering. This not only contributes to its excellent performance but also allows for fine azimuth and elevation adjustments. This feature is crucial in aligning the antenna accurately with satellite signals, further improving the quality of service for users.

Another key aspect of the Andrew ES76PK-1 is its compatibility with a range of RF systems. This versatility makes it a favored choice among service providers and enterprises looking to implement or upgrade their satellite communication infrastructure.

In summary, the Andrew ES76PK-1 stands out in the competitive landscape of satellite communication technologies. With its high gain, durable construction, advanced polarization, and compatibility with various systems, it meets the stringent demands of modern communication needs. This antenna is an excellent investment for anyone looking to achieve reliable and efficient satellite connectivity.
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