Compute RTO Generation Serving RTO Load Sample Clauses

Compute RTO Generation Serving RTO Load. Using the real-time generation output in MWs, compute the Generation serving RTO Load. Sum the output of RTO generation within each load zone: , for each RTO load zone Where: zone = the relevant RTO load zone; unit = the relevant generator; RTO_Genzone = the sum of the RTO’s generation in a zone; and Genunit,zone = the real-time output of the unit in a given zone. Next, reduce the RTO generation located within a load zone by the scheduled line real-time export transaction schedules that source from that particular load zone: Where: zone = the relevant RTO load zone; scheduled_line = each of the Transmission Facilities identified in Table 1 above; RTO_Reduced_Genzone = the sum of the RTO’s generation in a zone reduced by the sum of export schedules over scheduled lines from the zone; RTO_Genzone = the sum of the RTO’s generation in a zone; and Export_Schedulesscheduled_line,zone = export schedules from a zone over a scheduled line. The real-time export schedules over scheduled lines will only reduce the generation in the source zones identified in Table 1 above. The resulting generator output based on this reduction is defined below.
Sample 1Sample 2Sample 3See All (36)
AutoNDA by SimpleDocs
Compute RTO Generation Serving RTO Load. Using the real-time generation output in MWs, compute the Generation serving RTO Load. Sum the output of RTO generation within each load zone: _ = ∑ =1 ,, for each RTO load zone Where: zone = the relevant RTO load zone; unit = the relevant generator; RTO_Genzone = the sum of the RTO’s generation in a zone; and Genunit,zone = the real-time output of the unit in a given zone. Next, reduce the RTO generation located within a load zone by the scheduled line real-time export transaction schedules that source from that particular load zone: __ = _ − ∑ _ℎℎ_, Where: zone = the relevant RTO load zone; scheduled_line = each of the Transmission Facilities identified in Table 1 above; RTO_Reduced_Genzone = the sum of the RTO’s generation in a zone reduced by the sum of export schedules over scheduled lines from the zone; RTO_Genzone = the sum of the RTO’s generation in a zone; and Export_Schedulesscheduled_line,zone = export schedules from a zone over a scheduled line. The real-time export schedules over scheduled lines will only reduce the generation in the source zones identified in Table 1 above. The resulting generator output based on this reduction is defined below. Where: = , (__) _ unit = the relevant generator; zone = the relevant RTO load zone; Genunit,zone = the real-time output of the unit in a given zone; Reduced Genunit = each unit’s real-time output after reducing the RTO_Net_Gen by the real-time export schedules over scheduled lines; RTO_Reduced_Genzone = the sum of the RTO’s generation in a zone reduced by the sum of export schedules over scheduled lines from the zone; and RTO_Genzone = the sum of the RTO’s generation in a zone. Once export schedules over scheduled lines are accounted for, it is then appropriate to reduce the net RTO generation by the remaining real-time export schedules at the proxies identified in Table 2 above. Where: __ = ∑ __ =1 zone = the relevant RTO load zone; RTO_Net_Gen = the sum of the RTO’s generation reduced by the sum of export schedules over all scheduled lines; and RTO_Reduced_Genzone = the sum of the RTO’s generation in a zone reduced by the sum of export schedules over scheduled lines from the zone. __ = __ − ∑ _ℎ =1 Where: proxy = representation of defined sets of Transmission Facilities that (i) interconnect neighboring Balancing Authorities,
Sample 1Sample 2Sample 3See All (13)
Compute RTO Generation Serving RTO Load. Using the real-time generation output in MWs, compute the Generation serving RTO Load. Sum the output of RTO generation within each load zone: =1 _ = ∑ , , for each RTO load zone Where: zone = the relevant RTO load zone; unit = the relevant generator; RTO_Genzone = the sum of the RTO’s generation in a zone; and Genunit,zone = the real-time output of the unit in a given zone. Next, reduce the RTO generation located within a load zone by the scheduled line real-time export transaction schedules that source from that particular load zone: Where: __ = _ − ∑ _ℎℎ_, ℎ_=1 zone = the relevant RTO load zone; scheduled_line = each of the Transmission Facilities identified in Table 1 above; RTO_Reduced_Genzone = the sum of the RTO’s generation in a zone reduced by the sum of export schedules over scheduled lines from the zone; RTO_Genzone = the sum of the RTO’s generation in a zone; and Export_Schedulesscheduled_line,zone = export schedules from a zone over a scheduled line. The real-time export schedules over scheduled lines will only reduce the generation in the source zones identified in Table 1 above. The resulting generator output based on this reduction is defined below. Where: = ,
Sample 1Sample 2Sample 3See All (7)
Compute RTO Generation Serving RTO Load. Using the real-time generation output in MWs, compute the Generation serving RTO Load. Sum the output of RTO generation within each load zone: 𝑅𝑇𝑂_𝐺𝑒𝑛𝑧𝑜𝑛𝑒 𝑎𝑙𝑙 = ∑ 𝑢𝑛𝑖𝑡=1 𝐺𝑒𝑛𝑢𝑛𝑖𝑡,𝑧𝑜𝑛𝑒, for each RTO load zone Where: zone = the relevant RTO load zone; unit = the relevant generator; RTO_Genzone = the sum of the RTO’s generation in a zone; and Genunit,zone = the real-time output of the unit in a given zone. Next, reduce the RTO generation located within a load zone by the scheduled line real-time export transaction schedules that source from that particular load zone: 𝑎𝑙𝑙 𝑅𝑇𝑂_𝑅𝑒𝑑𝑢𝑐𝑒𝑑_𝐺𝑒𝑛𝑧𝑜𝑛𝑒 = 𝑅𝑇𝑂_𝐺𝑒𝑛𝑧𝑜𝑛𝑒 − � 𝐸𝑥𝑝𝑜𝑟𝑡_𝑆𝑐ℎ𝑒𝑑𝑢𝑙𝑒𝑠𝑠𝑐ℎ𝑒𝑑𝑢𝑙𝑒𝑑_𝑙𝑖𝑛𝑒,𝑧𝑜𝑛𝑒 𝑠𝑐ℎ𝑒𝑑𝑢𝑙𝑒𝑑_𝑙𝑖𝑛𝑒=1
Sample 1Sample 2Sample 3See All (5)
Compute RTO Generation Serving RTO Load. Using the real-time generation output in MWs, compute the Generation serving RTO Load. Sum the output of RTO generation within each load zone:
Sample 1

Related to Compute RTO Generation Serving RTO Load

  • Synchronous Generation The Interconnection Customer shall design its Small Generating Facility to maintain a composite power delivery at continuous rated power output at the Point of Interconnection at a power factor within the range of 0.95 leading to 0.95 lagging, unless the NYISO or the Transmission Owner in whose Transmission District the Small Generating Facility interconnects has established different requirements that apply to all similarly situated generators in the New York Control Area or Transmission District (as applicable) on a comparable basis, in accordance with Good Utility Practice.

  • Non-Synchronous Generation The Interconnection Customer shall design its Small Generating Facility to maintain a composite power delivery at continuous rated power output at the high-side of the generator substation at a power factor within the range of 0.95 leading to 0.95 lagging, unless the NYISO or the Transmission Owner in whose Transmission District the Small Generating Facility interconnects has established a different power factor range that applies to all similarly situated non-synchronous generators in the control area or Transmission District (as applicable) on a comparable basis, in accordance with Good Utility Practice. This power factor range standard shall be dynamic and can be met using, for example, power electronics designed to supply this level of reactive capability (taking into account any limitations due to voltage level, real power output, etc.) or fixed and switched capacitors, or a combination of the two. This requirement shall only apply to newly interconnecting non-synchronous generators that have not yet executed a Facilities Study Agreement as of September 21, 2016.

  • Interconnection Customer Provided Services The services provided by Interconnection Customer under this LGIA are set forth in Article 9.6 and Article 13.5.1. Interconnection Customer shall be paid for such services in accordance with Article 11.6.

  • Restricted Use By Outsourcers / Facilities Management, Service Bureaus or Other Third Parties Outsourcers, facilities management or service bureaus retained by Licensee shall have the right to use the Product to maintain Licensee’s business operations, including data processing, for the time period that they are engaged in such activities, provided that: 1) Licensee gives notice to Contractor of such party, site of intended use of the Product, and means of access; and 2) such party has executed, or agrees to execute, the Product manufacturer’s standard nondisclosure or restricted use agreement which executed agreement shall be accepted by the Contractor (“Non-Disclosure Agreement”); and 3) if such party is engaged in the business of facility management, outsourcing, service bureau or other services, such third party will maintain a logical or physical partition within its computer system so as to restrict use and access to the program to that portion solely dedicated to beneficial use for Licensee. In no event shall Licensee assume any liability for third party’s compliance with the terms of the Non-Disclosure Agreement, nor shall the Non-Disclosure Agreement create or impose any liabilities on the State or Licensee. Any third party with whom a Licensee has a relationship for a state function or business operation, shall have the temporary right to use Product (e.g., JAVA Applets), provided that such use shall be limited to the time period during which the third party is using the Product for the function or business activity.

  • Interconnection Service Interconnection Service allows the Interconnection Customer to connect the Large Generating Facility to the Participating TO’s Transmission System and be eligible to deliver the Large Generating Facility’s output using the available capacity of the CAISO Controlled Grid. To the extent the Interconnection Customer wants to receive Interconnection Service, the Participating TO shall construct facilities identified in Appendices A and C that the Participating TO is responsible to construct. Interconnection Service does not necessarily provide the Interconnection Customer with the capability to physically deliver the output of its Large Generating Facility to any particular load on the CAISO Controlled Grid without incurring congestion costs. In the event of transmission constraints on the CAISO Controlled Grid, the Interconnection Customer's Large Generating Facility shall be subject to the applicable congestion management procedures in the CAISO Tariff in the same manner as all other resources.

  • Scope of Interconnection Service 1.3.1 The NYISO will provide Energy Resource Interconnection Service to Interconnection Customer at the Point of Interconnection.

  • Availability of Verizon Telecommunications Services 3.1 Verizon will provide a Verizon Telecommunications Service to Reconex for resale pursuant to this Attachment where and to the same extent, but only where and to the same extent, that such Verizon Telecommunications Service is provided to Verizon’s Customers.

  • COMMERCIAL REUSE OF SERVICES The member or user herein agrees not to replicate, duplicate, copy, trade, sell, resell nor exploit for any commercial reason any part, use of, or access to 's sites.

  • Utility Services Company agrees to pay the full cost and expense associated with its use of all utilities, including but not limited to water, sanitary sewer, electric, storm drainage, and telecommunication services.

  • ELECTRICAL SERVICES A. Landlord shall provide electric power for a combined load of 3.0 xxxxx per square foot of useable area for lighting and for office machines through standard receptacles for the typical office space.

Time is Money Join Law Insider Premium to draft better contracts faster.