Sentences with phrase «kwh =»
E = mgh 100t x 1000 kg x 9.81 x 6m = 5.9 MJ 1 kWh = 3.6 MJ therefore a 100 tonne accumulator with a 6m stroke contains 1.6 kWh.
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Energy of 33.7 kWh = Energy of 1 gallon of gas 2.
Kelly, meanwhile, saves $ 500 / year (5,000 kWh / year x $ 0.10 / kWh = $ 500).
Pat's system produces 5,000 kWh per year, saving $ 250 / year in electricity costs (5,000 kWh / year x $ 0.05 / kWh = $ 250).
The annual total of $ 1.5 million is claimed «economic benefits» is equal to about 12.6 % of the $ 11.88 million in EXTRA costs loaded on electric customers each year if the full, true costs of the electricity from the «wind farm» were only $ 0.02 per kWh above the cost of electricity from other sources (i.e., 594,206,000 kWh x $ 0.02 per kWh = $ 11,884,120).
To get 33.7 kWhs to one gallon, they have basically done a conversion through BTUs — ie 1 KWh = 3412 BTU and one gallon of gasoline releases 115,000 BTU of energy in combustion.
So the extra insulation saves 309.1 kWh — 8.4 kWh = about 300 kWh per year.
If 10 000 water heaters are converted to using variable priced electricity (VPE), and supposing that the water in the heaters only needed a 15 °C boost, then up to 10 000 * 0.5 * 3.5 kWh = 17.5 MWh could be consumed at selected times each day to help stabilise the electricity distribution grid.
A reliable formula to calculate your actual cost of «fuel» (electricity) is to divide miles driven by MPGe (129 city, 102 hwy, 115 combined) and multiply by 33.7 (33.7 kwh = energy of one gallon of gas).
6.8 KWH = Ridiculous Battery capacity.
Not exact matches
0.173 kWh / km = 3.61 MPkWh (EU test) = 4.79 MPkWh (EPA test) @ 33.7 kWh / gallon (US) = 161MPG (US) e.
Where I live, a perfectly placed solar panel delivers 800 kWh per year per kWp (= kW peak rated capacity).
Therefore, to raise the temperature of 100L by 30 °C requires 100 000 * 30 * 4.19 watt seconds = 3492 watt hours, or = 3.492 kilowatt hours (kWh)
So the actual LCOE (anticipated by the producer) for 4c / kWh agreement is -LRB-(4c / kWh (PPA) + 2.2 c PTC) * (1 - margin of the producer) ~ 6.2 c * 0.8 = 4.96 c.
Instead of merely guessing; a simple calculation: cost of 1000 mw reactor $ 9E9 capacity factor = 0.9 Design life 50 yr wholesale price of electricity $.03 per kWh
Assuming $ 0.20 / kWh, 5 % discount rate, period of 30 years, and 2 % electricity inflation means that an investment of $ 392 is cost neutral, that is, Net Present Value = $ 0.
So 28 kKh / a * 0.3 W / K = 8.4 kWh / a.
Doing the math again: 0.184 W / mK * 60 m * 28 kKh / a = 309.1 kWh / a.
2016 Tesla Model S AWD - 70D EPA Fuel Economy 1 gallon of gasoline = 33.7 kWh Show electric charging stations near me Electricity Combined MPG: 101 MPGe City MPGe: 101 Highway MPGe: 102 combined city / highway city highway 33 kWh / 100 mi 240 miles Total Range About All - Electric Cars Unoffi...
the Finland costs at the bottom right with 32 - 65 % (= average of 10 - 20 %, but I'm unsure of their capacity factor) having costs of around $ 1 / MWh, or 0.1 c / kWh
Second, although the final cost per kWh of energy is not given, we can see that whereas in the GIV storage case we build 16GW solar, 90GW offshore wind, 124GW inland wind = 230GW peak, with centralized storage we build 50, 129, 61 = 240GW peak and probably need the expensive offshore wind as a more reliable (less intermittent) source than onshore wind.
the UK costs at the top of the graph, with peak penetration of 20 - 40 % (= average penetration of 6 - 12 %) having costs of around $ 5 / MWh, or 0.5 c / kWh
I = Insolation = 1000 Watts / m2 SPE = SP Conversion Eff =.4 (40 % of your figure) HPD = Hrs / Day = 6 G = kWH / yr / m2 = I * SPE * HPD * 365 / 1000 = 876 (36 % of your figure) LU = Land Utilization =.8
$ 33,000 / 92,000 = 36 c / kWh.
$ $ \ text -LCB- Average Daily Irradiance -RCB- = \ frac -LCB- \ text -LCB- Annual Irradiance -RCB--RCB--LCB- \ text -LCB- days / year -RCB--RCB- = \ frac -LCB- 1900 \ mathrm -LCB- kWh / m ^ 2 year -RCB--RCB--LCB- 365 \ mathrm -LCB- days / year -RCB--RCB- = \ mathrm -LCB- 5.2 \ mathrm -LCB- kWh / m ^ 2day -RCB--RCB- $ $
If we use the SCC of $ 33 / t C (i.e. $ 9 / t CO2) from IPCC AR5 WGII, Table 10 - 9, (for Post-AR4 3 % PRTP), the cost would be $ 9 / tonne CO2 x 0.93 t CO2 / MWh = $ 8.4 / MWh, or 0.84 c / kWh.
365.25 days / year = 8766 hours / year, thus 1 W = 8.766 kWh / yr.
1000 lbs of polyethylene = 188 lbs of oil and 827 lbs of natural gas and 159 kWh of electricity.
Wind turbine project installed cost: $ 2,000 / kW Typical mechanical life of a wind turbine: 20 years Hours per year: 8,760 Average availability of wind power: 24 % Market value of 1 kWh of electricity at production site: $ 0.07 Value of total electricity produced during wind turbine life: 20 x 8,760 x 0.24 x $ 0.07 = $ 2,943 / kW installed As you can see the payback on wind turbine projects is iffy even with no maintenance and operating costs included in the equation.
For comparison here is the same equation for a coal - fired power plant: Coal power project installed cost: $ 2,500 / kW (High end number — Some coal fired plants are built for $ 1,500 / kW) Typical life of a coal fired plant: 30 years Hours per year: 8,760 Average availability of coal - fired power plant: 88 % Total electricity production during plant life: 231,000 kWh / kW installed Value of electricity produced: $ 16,188 / kW installed Lifetime Cost of fuel = 231,000 x $ 0.006 = $ 1,388 / kW installed Net Value of total electricity produced during plant life: $ 14,800 / kW installed.
The «market» value of the electricity produced in one year (75,000 x 0.3 x 24 x 365 = 197 million kWh) is between $ 80MM and $ 90MM at those rates which quickly pays for the $ 75MM estimated project cost.
= 31,900 KWh.
EPA Fuel Economy 1 gallon of gasoline = 33.7 kWh Show electric charging stations near me Electricity Combined MPG: 112 MPGe City MPGe: 125 Highway MPGe: 100 combined city / highway city highway 30 kWh / 100 mi 151 miles Total Range About All - Electric Cars Unofficial MPG Estimates from Vehic...