Sterling STT 800 manual Dehumidified Air Dryer For the safety of the devices

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Dehumidified Air Dryer

2.2. For the safety of the devices

Never change settings without carefully assessing the consequences.

Use only original Sterling spare parts.

Observe the maintenance instructions.

Keep a record of all maintenance works and repairs.

Please note that electronic components can be damaged by static discharge.

Before initial operation and in regular intervals, make sure that no electrical connections are loo- se.

Never readjust sensors without exactly knowing their functions.

Please ensure that the permitted storage temperature lies between -20 and +55 °C (-4 to +131 °F).

Please ensure that the permitted operation temperature lies between 0 and +45 °C (32 to +113 °F).

Check the direction of rotation of the blowers after the electrical connections have been made (see rotational direction arrow).

Clean the drying hoppers before the first filling.

Note the instructions of the material manufacturer for the maximum drying temperature.

Note the drying instructions of the material manufacturer.

Take care that the drying hoppers are always completely filled and that the retention period is re- spected if continual removal is taking place.

Note that too large amounts taken from the drying hopper lead to insufficient drying of the materi- al.

Close the air stop valves of drying hoppers which are empty or have not been used.

Note down all data which you have entered into the control system.

The password is to be entrusted to authorised personnel only.

Please note that the temperature of the dryer heating system must always be set lower than that of the supplementary heaters.

When you dispose of drying agents, observe all official rules.

Note that drying cells are replaced or refilled by Sterling only if they are empty.

The material level may not fall below 40 % in the drying hopper, when material is continuously re- moved from the drying hopper, but no material is continuously fed into the drying hopper (batch drying). Close the throttle valves.

Read the operating manuals of the connected devices.

SM2-625

Safety instructions 2-5

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Contents Sterling Material Processing Parts and Service Department Edition 06/02 Order confirmation number STT Sterling Material ProcessingSTT Table of Contents Transport, Assembly and Storage Spare parts list General Information Dehumidified Air DryerGeneral Information Dehumidified Air Dryer Dehumidified Air Dryer Explanations and information Legal basisFields of applications Safety instructions Safety instructionsGeneral Dehumidified Air Dryer For your safetyOperation AssemblyMaintenance Dehumidified Air Dryer For the safety of the devices Start-up Start-upKey assignment STT Control systemIndicator lamp messages STT Flow chartOperation statuses STT Switching on the dryerSTT Viewing the software-version PasswordsLogin LogoutEdit Dryer on/off Timer on/offSTT Basic parameters Turning the devices on/offSTT Dew point max STT Entering dryer valuesRegeneration Heater Act Used air ActPre air cooler Act Pre air cooler TargetSTT Entering hopper values Hopper entry X TargetHopper entry X Act Granules Act. CF Granules Target % = C FSTT Observing processing status Valve block moved in/moved out/errorSTT Setting date and time DateTime STT Viewing/changing language and contrast ContrastLanguage Parameters STT Changing parametersSelect Parameters Run on time drying blower -- 300 secSTT Setting the timer XX on 0000 OFF 0000 XX = day Mo-SuExample Select Main menu STT Starting continuous operationXX h STT Viewing system runtimeSelect System runtime System runtimeSTT Switching the dryer off Error and error correction Error and error correctionLED Alarm View Delete NumberTotal messages Waiting messagesOverflow warning On/Off OverflowSafety Switch Drying Blower Has Been Actuated Main Switch is OffSafety Temperature Limiter has been Activated Safety Switch Regeneration Blower Has Been ActuatedSafety Switch Regeneration Heater Has Been Actuated Temperature Measurement Regeneration Heater DefectiveExcess Temperature Regeneration Heater Insufficient Temperature Regeneration HeaterSafety Switch Drying Heater Temperature Measurement Drying Heater DefectiveExcess Temperature Drying Heater Insufficient Temperature Drying HeaterTemperature Measurement Pre Air Defective Temperature Measurement Granules Defective HopperExcess Temperature Granules Hopper Valve Error HopperMaintenance MaintenanceSTT STT Maintenance intervals STT Cleaning/renewing the air filters Return air filter Regeneration air filter Filter of the electrical cabinet STT Tensioning the V-belts Blower regeneration heater / Blower drying heater Servicing the accessories Disposing of the drying agentHigh-pressure blowers with frequency converter operation STT Changing the battery of the control system STT STT Resetting the control values Functional description Functional descriptionSTT Dryer Dew point dependent regeneration switch optionalSTT Drying hopper optional Pre air cooler optional STT Return air cooler optionalSTT Hopper heaters optional Automatic motor flaps optionalConnection to a pneumatic conveying system optional Transport, Assembly and Storage Transport, Assembly and StorageWith a fork lift truck Dehumidified Air Dryer Transport and PackingWith a workshop crane Storage Dehumidified Air Dryer AssemblyAssembly instructions Assembly instructionsConnection of the air coolers optional Dehumidified Air Dryer Electrical connection Optional Equipment Technical DataTechnical Data Basic EquipmentDimension sheet Spare parts list Spare parts listSpare parts list Pos. ID-number Description Flaps optional Switching Cabinet and Operating UnitAccessories Return air cooler optionalElectrical manual Electrical manualAccessories AccessoriesAccessories Entering values on the OP 7 Entering Values Entering Numerical Values Entering Alphanumeric Values Step Procedure Entering Symbolic Values Accessories Flap control with Fuzzy-Logic Control unit flap Flap control with Fuzzy-Logic

STT 800 specifications

The Sterling STT 800 is an advanced thrust vector control system that has garnered significant attention in the aerospace and defense sectors. Designed to enhance the performance of various aircraft, including drones and missiles, the STT 800 combines cutting-edge technologies and innovative design to provide operators with exceptional maneuverability and precision.

One of the primary features of the Sterling STT 800 is its state-of-the-art thrust vectoring capability. This technology allows the aircraft to change the direction of its thrust, enabling unparalleled agility and control during flight. By directing engine thrust both horizontally and vertically, the STT 800 can perform complex aerial maneuvers that standard aircraft would struggle to achieve. This capability is critical for modern combat scenarios, where quick evasive actions and sharp turns can mean the difference between mission success and failure.

The STT 800 is built with lightweight, robust materials that enhance its durability while minimizing overall weight. This design philosophy ensures that the system remains operable under extreme conditions, including high-speed flight and challenging environmental situations. Advanced materials not only contribute to the overall performance of the system but also improve its resistance to wear and tear.

Another key characteristic of the Sterling STT 800 is its integration with advanced navigation and control systems. The aircraft can utilize GPS, inertial navigation systems, and state-of-the-art avionics to maintain high levels of situational awareness and operational efficiency. This integration enables seamless communication between components, allowing for real-time adjustments and data sharing during flight.

The STT 800 is also designed with modularity in mind, allowing for easy upgrades and the incorporation of future technologies. This adaptability ensures that operators can keep pace with the rapidly evolving landscape of aerospace technology, maintaining a competitive edge in both military and civilian applications.

In addition, the Sterling STT 800 features advanced software algorithms that optimize flight paths and enhance overall efficiency. This intelligent system provides operators with predictive analytics, ensuring that the aircraft can adapt to changing conditions and mission objectives effectively.

Overall, the Sterling STT 800 represents a significant leap forward in thrust vector control technology. With its combination of advanced maneuverability, durable design, sophisticated navigation systems, and modularity, it exemplifies the capabilities required for modern aerial operations and sets a new standard for performance in the aerospace industry.
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