Application Guide Sample Clauses

Application Guide. When the employer determines the job requirement group for the employee, this determination shall be based on the requirements of the employee’s duties. If the employee’s duties include tasks from different job requirement groups, the employee’s job requirement group is determined based on his or her primary duties or by determining a weighted job requirement group for the times spent in duties belonging to different job requirement groups. Using these times requires a task-specific working time record, or if this is not available, a work plan.

Application Guide. In principle, the employer’s consent applies always, except in cases where the absence of work constitutes an unauthorised absence.

Application Guide. SERIES CAPACITORS The impedance, normal rating, long time emergency rating, short time emergency rating, drastic action limit, and short circuit current withstand rating of a series capacitor bank shall be the values provided by the manufacturer or calculated by the owner at 60 Hertz and nominal system voltage e.g. 69 kV, 115 kV, 230 kV or 345 kV consistent with IEEE Standard 824. SHUNT CAPACITORS The kVA rating of a shunt capacitor bank shall be the rating provided by the manufacturer or calculated by the owner at 60 Hertz and nominal system voltage e.g. 69 kV, 115 kV, 230 kV or 345 kV consistent with IEEE Standard 18. SERIES REACTORS The impedance, losses, normal rating, long time emergency rating, short time emergency rating, drastic action limit, and short circuit current withstand rating of a series reactor bank shall be the values provided by the manufacturer or calculated by the owner at 60 Hertz and nominal system voltage e.g. 69 kV, 115 kV, 230 kV or 345 kV consistent with IEEE Standard C57.21. SHUNT REACTORS The kVA rating, losses and impedance of a shunt reactor shall be the values provided by the manufacturer or calculated by the owner at 60 Hertz and nominal system voltage e.g. 69 kV, 115 kV, 230 kV or 345 kV. The impedance of the shunt reactor shall be measured at full voltage as described in IEEE Standard C57.21.

Application Guide. RIGID SUBSTATION BUSES The ampacity rating calculations of rigid, Aluminum or Copper, outdoor, exposed non-enclosed buses and conductors involves parameters such as ambient temperature, maximum conductor temperature limitations, wind speed, wind direction, solar gain, emissivity, and absorptivity. The maximum temperature at which the bus can operate is limited by loss of strength (loss of life) due to temperature cycles and mechanical movement due to expansion. Rigid substation bus ratings shall be assigned in accordance with IEEE Standard 605-1998.

Application Guide. The use of working times in accordance with the work roster is based on the company’s production needs and/or the needs of the employees. The working time in accordance with the work roster refers to shifts, the length of which can vary between four and ten hours. There can be several shifts of varying lengths in a week. The lengths of the shifts can also vary weekly or monthly. The weekly working hours can vary in shifts referred to in the work roster. However, the regular working time shall not exceed 50 hours. The weekly working time must average out at 40 hours in a period of 52 weeks. This must be considered when compiling the work roster and when monitoring working time based on that roster.

Application Guide. Life Cycle Costing, which is a very general standard that identifies typical LCC analysis elements. 695 The scope of the LCC analysis framework detailed in ISO 15663 applies to: 696 the process concept, 697 equipment location (i.e. islanded or integrated solution), 698 project execution strategies, 699 Health, Safety and Environment (HSE) aspects, 700 system concept and sizing, 701 equipment type, 702 equipment configuration, 703 layout, 704 maintenance and operation strategies, 705 operating crew (e.g. ▇▇▇▇▇▇▇) strategies, 10 Although ISO 15686-5:2008-06-15, Buildings and constructed assets -- Service-life planning -- Part 5: Life-cycle costing provides a methodology that could also be applicable to small-scale FB systems designed specifically for building applications, the methodology and examples provided in ISO 15663 is more relevant to all possible scales (i.e. cabinet, containerised, and bespoke) of FB systems. 706 logistic support strategies, 707 facility modifications (N.B. closely related to Process Safety – Management of Change described in 708 Section 7), 709 spares and technical support strategies, 710 decommissioning and recycling strategies. 711 All definitions, terms and abbreviations provided in ISO 15663, Section 2 are sufficiently generic as to be 712 applicable to Flow Battery Storage Systems, and should be adopted for all Flow Battery Storage System LCC 713 analyses. 714 The organisation and planning process described in ISO 15663, Section 3 is also sufficiently generic as to be 715 applicable to Flow Battery Storage System projects, as this section describes roles and processes that are 716 already in place in many organisations. 717 The core of ISO 15663-1 is Section 4, which describes the methodology in detail. As with the previous 718 sections already described, the methodology described is generic in terms of its application to a technological 719 system that it can be immediately applied to a Flow Battery Storage System. 720 NOTE the methodology is not sufficiently detailed for component-level costing: this is stated clearly in Section 1 of 721 the standard. 722 Section 5 provides a checklist of tasks that should be completed prior to finalising the LCC analysis. 723 After establishing the generic methodology in ISO 15663-1, a subsequent standard, ISO 15663-2, Petroleum 724 and Natural Gas Industries – Life-cycle costing Guidance on application of methodology and calculation 725 methods, provides additional details for applying th...

Application Guide. Line trap ratings shall be calculated using one of the methods described below at a rated power frequency of 60 Hertz and nominal voltage, e.g. 69 kV, 115 kV, 230 kV or 345 kV. Line Traps have limited overload capacity; therefore the continuous current rating should be selected to be above the winter four-hour emergency rating of the circuit in which it is installed. Furthermore, Line Traps must have a higher short-circuit capability and a continuous current rating greater than other any of the other components in the circuit (i.e. circuit breakers, disconnect switches, etc). RATING ALGORITHMS The rating methods used by various manufacturers are based on the following common elements:  Ambient temperature ( a );  Temperature rise, which is a function of the I2R losses;  A pre-determined maximum temperature acceptable for various line traps under normal and emergency conditions;  Acceptable limits of loss of life of line trap due to the above. NORMAL RATINGS The primary considerations in defining the normal current rating of a line trap are ambient temperature and maximum allowable temperature rise. In the absence of a heat run tests, the manufacturer can calculate the normal current rating by a compensation method for a specific ambient temperature. Based on the premise that hottest spot temperature rise is proportional to I2R losses, the following equation can be used to determine a normal capability at any ambient temperature without exceeding the hottest spot design limit: TH  TA TH  TD IA = ID Where, IA = capability at ambient TA (amperes) ID = nominal rating of line trap, rated continuous current (amperes) TH = maximum hottest spot design temperature1 (C) TA = ambient temperature2 (C) TD = design ambient temperature3 (C) EMERGENCY RATINGS When defining the emergency current rating of a line trap, for ratings of twenty-four hours and less in duration, the emergency allowable maximum temperature limits of 30C above the normal allowable maximum temperature shall be utilized. Operation at the specified emergency allowable maximum temperatures shall not affect the accuracy of the tuning pack in the line trap. NEMA Standard SG-11 [Reference 1] specifies that the resonant frequency shall not vary more than two percent for ambient temperatures within the range of minus 40C to plus 40C. Emergency ratings for durations of less than two hours are determined based on the line trap’s Thermal Time Constant, which is a function of the heat storage capac...

Application Guide. Current Transformer (CT) circuit component ratings shall be determined as described below at a rated power frequency of 60 Hertz. While the thermal capabilities of relays vary by manufacturer and application, the relays and associated equipment conform to the applicable ANSI/IEEE and IEC Standards noted in References 1, 2, 3 and 4. Therefore, ratings shall be based on information provided by the manufacturer. Furthermore, the individual owners are to confirm, with the manufacturers involved, that the associated current transformer circuit components (i.e. meters, transducers, relays, etc…) are not the limiting component of the transmission circuit. Guidance on the thermal capabilities of older relays and other connected equipment used in CT secondary circuits is provided in Attachment 4 of this document [Reference 5]. However, these lists do not include all possible or more recently available current transformer circuit components.

Application Guide. A Guide for the Preparation and Submission of NSF Applications via ▇▇▇▇▇▇.▇▇▇ guidelines apply (Note: The NSF ▇▇▇▇▇▇.▇▇▇ Application Guide is available on the ▇▇▇▇▇▇.▇▇▇ website and on the NSF website at: ▇▇▇▇▇://▇▇▇.▇▇▇.▇▇▇/publications/pub_summ.jsp? ods_key=grantsgovguide).