Athena Technologies 16C instruction manual Alarm Output Type

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Output Menu

Note: The Control Menu does not apply to an Alarm Output Type; therefore, the Control Menu does not appear.

Alarms A1 & A2 can be set up using this same information

in themenu.

Alarm Output Type

Display Parameter

Selection

Output 1 Alarm Action

 

 

(Latching)

 

(Normal)

Output 1 Alarm Operation

(Process Low)

 

(Process High)

 

(Inverse Band)

 

(Normal Band)

 

(Deviation Low)

 

(Deviation High)

Output 1 Alarm Delay

0-9999 sec

Output 1 Alarm Inhibit

0-9999 sec

Output 1 Alarm Setpoint

Span of Sensor

Output 2 Alarm Action

 

 

(Latching)

 

(Normal)

Output 2 Alarm Operation

(Process Low)

 

(Process High)

 

(Inverse Band)

 

(Normal Band)

 

(Deviation Low)

 

(Deviation High)

Output 2 Alarm Delay*

0-9999 sec

Output 2 Alarm Inhibit**

0-9999 sec

Output 2 Alarm Setpoint

Span of Sensor

*Alarm Delay - the time delay between the detection of the alarm condition and the initiation and indication of the output action.

**Alarm Inhibit - prevents low setpoint alarm activation during cold startup applications.

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Contents 16C Introduction Precautions FeaturesSafety Warning Contents Installation Mounting DimensionsContact Identification WiringRTDs. Connect 2-wire RTDs Make sure that you are using Appropriate thermocoupleWire, if necessary, to minimize Lead resistance. For long runs Wire RTDs should be usedA 120/240 Vac relay, but normally closed output 2 only Output TypesMode/Enter Key Menu Access KeyLower Key Raise KeySecurity Level, Menu System, and Operating Mode Power OnSecurity Levels Security Levels and Access RestrictionsManual Operating ModesMenu System Overview Been installed. Pressing the Menu Access key indexesMenu System Overview Menu SystemChart of Series 16C Menu System Security Levels On Next See options manual for parameter selections Descriptions Menus and ParameterDisplay Parameter Selection Input MenuJMPØ2 Output Menu Display MenuDisplay Parameter Output Menu Control Menu Output Type Recommended Setting secondsParameter Selection On/Off Output TypeBelow alarm setting Setpoint. High process alarmDeviation Alarm Alarm Output Type Autotune Damping Menu Recipe Ramp/ Soak Menu Eter should be set to which will disable itPower Fail Resume Supervisor Menu Options Menu Calibration MenuTo place the controller in Autotune mode AutotuningAutotuning Procedure Diagram Band Manual TuningNumber is the correct Derivative Time SecondsPossible error codes are Error CodesDisplay Problem Actions Technical Specifications Thermocouple Platinum 2- and 3-wire, 100 ohms atMaximum lead resistance 100 ohms For rated accuracyModel Input Calibration Type Ordering CodesRTD Calibration Values Quick-Helps Press and hold For 3 sec + PV + Two-Year Limited Warranty Warranty RepairsOther than those expressly stated herein, There are no BUYER’S Remedy is Limited to Either i Repair orUnit Repairs Fuse rating=100 mA Requirements250 Vpk 20 mA Glossary Applications for On/Off Control Quick Setup Instructions Series 16C Temperature Controller Configured Parameters Reference Data Page For Toll-FreeTechnical Assistance in the USA Call Toll Free

16C specifications

Athena Technologies is making waves in the aerospace and defense industries with its latest innovation, the Athena Technologies 16C. This advanced system is designed to provide detailed and accurate guidance, navigation, and control for unmanned aerial vehicles (UAVs) and other applications requiring precise positioning and situational awareness.

At the core of the Athena Technologies 16C is its state-of-the-art inertial navigation system. Utilizing a combination of accelerometers, gyroscopes, and advanced sensor fusion techniques, the 16C achieves exceptional accuracy even in challenging environments where GPS signals may be weak or nonexistent. This capability is crucial for military operations and search-and-rescue missions where precision is paramount.

One of the standout features of the 16C is its integrated multi-sensor environment, which includes not only traditional inertial sensors but also GPS, magnetometers, and barometric altimeters. This robust multi-sensor fusion system leverages cutting-edge algorithms to minimize errors, enhance reliability, and provide continuous position tracking regardless of external conditions. The flexibility of the sensor suite allows for easy integration into various platforms, whether fixed-wing, rotary-wing, or even ground-based vehicles.

Furthermore, Athena Technologies has prioritized ease of use with the 16C. The system comes equipped with intuitive software that simplifies mission planning and vehicle control. Users can easily adjust parameters, visualize data, and receive real-time feedback during operations, enhancing overall mission effectiveness. The user interface is designed to be user-friendly, catering to both experienced operators and newcomers to UAV technology.

Another notable characteristic of the Athena Technologies 16C is its rugged design, built to withstand harsh environmental conditions. This durability makes it suitable for deployment in diverse terrains and climates, ensuring reliable performance under even the most demanding situations. The system is lightweight yet robust, contributing to the overall efficiency and performance of unmanned systems.

Lastly, Athena Technologies emphasizes safety and security with the 16C. Advanced encryption methods safeguard the data transmitted between the system and ground control, ensuring that sensitive information remains protected from potential cyber threats. This commitment to security is crucial for military applications where data integrity is non-negotiable.

In conclusion, the Athena Technologies 16C stands out as a game-changing solution in the fields of guidance, navigation, and control. Its advanced multi-sensor capabilities, user-friendly interface, rugged design, and emphasis on security make it an essential tool for a wide range of applications, from military operations to commercial UAV usage. As technology continues to evolve, the 16C is poised to play a significant role in shaping the future of unmanned systems.