Energy Production. The second portion the 1990 inventory includes those emissions created during energy production and distribution.
Energy Production. As of 2020, energy production in Växjö is renewable. The Växjö Energy Plan emphasises in particular the ambition to increase local electricity generation to at least match local use. This means continuing to actively contribute to increased electricity production from biofuel-based cogeneration, wind, solar and water. This has become an even more important aspect to focus on, given the developments regarding electricity supply in Sweden and Europe in 2022. That said, there is a need to ensure that electricity use is optimised and continues to decrease, and that the electricity generated is used for the right purposes. This will help to make Växjö more resilient to power shortages, and to reduce the climate impact of Nordic electricity production. We are continuing to examine the options for production of renewable fuels in connection with the Sandviksverket combined power and heating plant, such as aviation biofuel or hydrogen, and our ambition is to increase biogas production. We secure energy raw materials without sacrificing biodiversity, which is vital as most of Växjö’s energy production originates from forest residues.
Energy Production. Guarantee In repect of the PB40ES PowerBuoy and mooring system, the CONTRACTOR guarantees fulfilment of an Energy Production of at least 50% of that predicted according to the Theoretical Power Table contained in table 1 of Annex XIV using the real wave data captured during the Testing Period of the PB40ES PowerBuoy and mooring system in the method described in Clause 21.4. In the event of breach of this guarantee that results in the delay of the DAC of the PB40ES PowerBuoy and mooring system beyond the date included in Clause 31, the remedies set forth in Clause 31 shall apply. 21.1.6
Energy Production. You understand that the module(s) will be used to produce electricity and that the electricity generated from your module(s) will be part of the community power supply. The amount of electricity produced by your module(s) will be calculated based on the amount of electricity produced in the aggregate from all of the modules in the CSG, divided by the number of modules, regardless of whether all modules are functioning at that time. You will receive a net metering credit against the amount due from DLPU for providing electric service to your DLPU service address, as provided in paragraph 5 of this agreement. The net metering system will also measure that amount of electricity drawn from the electrical grid and used by you at your service address. Absence unusual circumstances, your module(s) will not generate electricity for a specified period in excess of the amount of electricity expected to be consumed at your service address during that specified period. No representation or guaranty is made by DLPU regarding the actual amount of electricity that each module will produce or the amount of electricity production that will be allocated to each module.
Energy Production a) hydro-electric power plants and their associated works;
Energy Production. The electric grid in Madeira island is fed by five sources of energy, namely: hydro, wind, photovoltaic, solid waste incineration, and thermal energy from burning fossil fuels like diesel and natural gas. Despite an already considerable renewable energy production (between July 2016 and June 2017, electricity production was made up by around 30% of renewable sources), the demand is largely covered by fossil fuels. As of this writing, hydric power is the leading renewable energy production, followed by wind and solar power. As Figure 7.2 shows, the variation in renewable energy capacity and penetration is significant. The highest share of renewables in the mix usually happens between Winter and Spring, mostly driven by the increase in the production of the hydro plants. Figure 7.2: Monthly energy mix in Madeira island between July 2016 and June 2017. Concerning independent producer installations, the predominant renewable energy is solar energy. As of this writing, there are around 783 distributed solar micro and mini-producers, with a total installed capacity around 20MW. In 2016, the global energy issued by these generating power systems was around 29 GWh. The typical southern Mediterranean climate with high solar radiation characterizing Madeira, makes the Island a promising location for PV usage. Indeed, with an average of the daily solar energy incident that varies from 4 to 5 kWh/m2 and sunshine hours ranging from 1800 to 2600 per year, future scenarios predict an increase in its penetration. Goals and grid constraints One of the main objective of the local DSO is increasing the injection of renewables in the grid, as such sources can amount to an increase in provisioning security and efficiency benefits. At the same time, the instability of these sources represents the main blocking force for their penetration, especially in the case of a small-scale and completely isolated grid as the one of Madeira. Particularly, the increase of solar energy (which is the most unpredictable renewable source), associated with low consumption and high production periods (normally around midday), low voltage distribution networks and dispersed production facilities, represents a very difficult business case for the local DSO, as it tends to result in the phenomena of voltage increase (VI) and frequency fluctuations (FF). The fuzziness of the generation of PVs makes even more difficult the matching between generation and load demand, which leads to interruptions and ba...
Energy Production a. Kilowatt-hours produced by the PV systems will be measured using automated metering. Projected energy production is shown in Table E-2 below and is assumed to degrade by 0.5% per year.
Energy Production. You understand that your Module(s) will be used to produce electricity as part of the CSG and that the electricity generated from your Module(s) will be part of the community power supply. The amount of electricity produced by your Module(s) will be calculated based on the amount of electricity produced in the aggregate from all of the modules in the CSG, divided by the number of modules, regardless of the amount of electricity produced by a particular module or whether all modules are functioning at that time. You will receive a net metering credit against the amount due from BMU for electric service provided to your BMU service address, as provided for in paragraph 5 of this Agreement. The net metering system will also measure that amount of electricity drawn from the electrical grid and used by you at your service address. Your Module(s) will not generate electricity for a specified period in excess of the amount of electricity expected to be consumed at your service address during that specified period. No representation or guaranty is made by BMU regarding the actual amount of electricity that each module will produce or the amount of electricity production that will be allocated to each module.
Energy Production. Average 85 percent capacity factor, a rate that will produce
Energy Production. 13.1. You acknowledge and agree that there are several factors that may negatively impact the production of Energy by the Plant, these include without being limited to:
