Theory of Operation Sample Clauses
The 'Theory of Operation' clause defines the underlying principles and mechanisms by which a product, system, or process functions. It typically outlines the technical or operational logic, describing the sequence of actions, components involved, and how they interact to achieve the intended result. For example, in a contract for a piece of equipment, this clause might detail how the equipment processes inputs to produce outputs. Its core practical function is to provide a clear understanding of how the subject matter operates, ensuring all parties have a shared technical baseline and reducing the risk of misunderstandings or disputes about functionality.
Theory of Operation. This project is intended to provide an extension of Comcast’s internal PBX network to include outside parties (outsourcers). This could include, but not be limited to, configurations where the outsourcer “agents” will appear no differently than Comcast employees which are also configured as agents off the same PBX’s. As an option, Comcast may choose, at least initially, to utilize a trunk-side connection to facilitate connectivity between Comcast PBX’s and the outsourcer PBX’s.
Theory of Operation. INTRUSION ALARM SYSTEM General Scope of Work - Perimeter Window and Door Alarm Contact Schedule as follows - Interior Trap Protection - Motion detectors to be installed to provide protection as follows: Alarm System Arm/Disarm Control -
Theory of Operation. The H-340SDI has a built-in microprocessor which monitors the tipping bucket sensor. Whenever a bucket tip occurs the microprocessor wakes up from its low power sleep mode and adds an appropriate rainfall increment to the rainfall accumulators. The electronics has a filter circuit which prevents contact bounce in the bucket tip ▇▇▇▇ switch from causing false counts. In addition, the time between bucket tips is measured, bucket tips which occur less than 500mS apart are ignored. This helps protect from false counts of a poorly adjusted bucket mechanism. The H-340SDI protects its rainfall accumulations with a software flag or “signature.” If the power is interrupted momentarily the H-340SDI will resume operation using the accumulation values in memory. If the power is lost long enough to destroy the signature, when the power is restored the H-340SDI resets the rainfall accumulators to 0000. To intentionally reset the H-340SDI's accumulators, disconnect the power for 5 to 10 seconds or use the extended “aXRA” command. The H-340SDI provides daily rainfall accumulation values which are useful for data loggers which do not have special provisions for computing daily rainfall. The H-340SDI has a built-in real-time-clock which triggers a “daily reset time” event. When this event occurs the H-340SDI automatically updates its “yesterday’s total accumulation” value using “today’s total accumulation”, then zeros the “today’s total accumulation” value. During normal operation, the data recorder sends an address together with a command to the H-340SDI sensor. The H-340SDI wakes up from its low power sleep mode and stores the requested data in its data buffer. Once the data is ready, the data recorder collects the data from the H-340SDI's data buffer.
Theory of Operation. The following information on operating parameters and maintenance requirements are essential to the success of the project, as agreed upon with Customer and ESCO. Table 1 outlines the baseline operational parameters for the aeration process. Table 2 outlines the operational parameters for the aeration process during the Performance Period. Table 1: Baseline Theory of Operations Aeration Process TSWRRF – Central & East Aeration Trains • Anoxic zones are located immediately upstream of the two aeration basins where primary effluent and RAS TSWRRF – Central Train • 2 of 2 basins in service. are subjected to anoxic conditions. Chemically bound oxygen is provided via a nitrate-rich mixed liquor fed from each aeration basin. Mixers run continuously to maintain anoxic conditions. • Airflow is provided to each aeration basin zone and controlled to maintain the following D.O. setpoints: ▇▇▇▇▇▇▇ ▇▇▇▇▇ ▇▇▇ ▇▇▇▇▇ ▇▇ & 2A – 2.6 mg/L ▇▇▇▇▇▇▇ ▇▇▇▇▇ ▇▇▇ ▇▇▇▇▇ 1B & 2B – 2.6 mg/L ▇▇▇▇▇▇▇ ▇▇▇▇▇ ▇▇▇ ▇▇▇▇▇ ▇▇,▇▇,▇▇,▇▇ – 2.4 mg/L ▇▇▇▇▇▇▇ ▇▇▇▇▇ ▇▇▇ ▇▇▇▇▇ ▇▇,▇▇,▇▇,▇▇ – 2.4 mg/L East Basin 3 Zone 3 – 3.5 mg/L East Basin 4 Zone 3 – 2.0 mg/L East Basin 3 Zone 4 – 3.5 mg/L East Basin 4 Zone 4 – 2.0 mg/L • MLR pumps, located in aerated zones, run continuously to feed a sufficient amount of nitrates from the aerobic zones to the anoxic zones. The pump motors are operated at a constant 100% speed. • Additional aeration is provided to a Central Train pre- nitrification basin where the solids dewatering recycle stream, that is high in ammonia, is pre-treated before entering the Central Train aeration basins. Airflow is controlled to maintain a D.O. setpoint of 1.9 mg/L. • Aeration zone valves are modulated to maintain the airflow setpoint which is based off D.O setpoint. • Solids Retention Time is controlled to a constant user- defined value based using a solids density probe in the RAS/WAS stream. TSWRRF – Combined Air Header • An LPA (low pressure compressed air) piping system supplies air to Central and East aeration zones. • LPA header pressure setpoint floats and is calculated based off aeration zone valve positions. • East Train Blower 1&2 and Central Train Blower 1 supply compressed air to the LPS system. Airflow piping for each train is combined to allow any connected blower(s) to meet the total Central and East train airflow demand. • Blower capacity is controlled to meet the LPA header pressure setpoint by modulation of blower inlet vanes and discharge diffusers. • An LPA Air Bl...
Theory of Operation. To provide 2-3 days of usable antimicrobial performance in a silver-coated wound dressing. • The dressing will provide antimicrobial activity through a sustained release of silver, which will minimize bacterial penetration to the wound and within the dressing.