Sentences with phrase «peak load of»
In their program, certification required hitting an annual load at or below 4.75 thousand BTU per square foot per year or a peak load of 3.17 thousand BTU per hour per square foot.
https://www.energyvanguard.com/
PacifiCorp, a large utility in the northwestern United States, operates a system with a peak load of 8,300 MW that is expected to grow to 10,000 MW over the next decade.
In the two years since the nuclear moratorium, the nation has urgently needed new baseload power plants to shoulder the country's annual peak load of 80 GW.
With a peak load of 719 megawatts, we deliver a safe and reliable supply of electricity to over 152,549 customers from the residential, institutional, commercial and industrial sectors, through 2,820 kilometres of overhead and underground cables, spanning 420 square kilometres of service territory.
Not exact matches
A chemically aged battery also becomes less capable of delivering peak energy loads, especially in a low state of charge, which may result in a device unexpectedly shutting itself down in some situations.
Powerpack systems support applications including peak shaving, load shifting and demand response for commercial customers while offering renewable firming and a variety of grid services at utility scales.
By keeping cash in reserve, you should counterintuitively load up on stocks right at the times of peak selling.
Goldman, Citi and the rest of the gentlemanly, altruistic global banks invented yet another disgraceful product at or around the peak of the stock market a couple of years back and they aimed it, not unlike a loaded gun, squarely at the foreheads of wealthy Chinese businessmen.
With a contract now in place between Tesla and the Australian Energy Market Operator (AEMO), the battery «will help solve power outages, reduce intermittencies, and manage summertime peak load to support the reliability of South Australia's electrical infrastructure, providing enough power for more than 30,000 homes — approximately equal to the amount of homes that lost power during the blackout period last year,» Tesla said in a statement.
We look forward to this all year long, and with good reason: When picked at the peak of ripeness, this grain is loaded with sweet, tender kernels that are great for boiling and slathering with butter, grilling, sautéing, or just eating raw.
Given the makeup of Chicago's roster and its implementation of the triangle, this was probably Pippen's maximum offensive output, as he peaked in offensive load at 43 (96th percentile) while the Bulls posted a respectable +2.2 rORtg when healthy, better than any offense Michael Jordan led before Phil Jackson arrived.5
It's because he can see into the future and see who has reached his peak and who has still got loads of unearthed potential hidden in them.
An offshore wind farm at the center of a LIPA plan to address spiking electric demand on the South Fork will produce excess energy when it's needed least, and fall short of a sharply expanding summer peak load, a recent analysis found.
As a means to cut down on double - parking and disruptive deliveries, the city will also pilot banning curbside loading entirely during peak hours in a large swath of midtown — from 45th Street to 50th Street, between Sixth Avenue and Madison Avenue.
But if they can play the role of trusty sidekick, reducing the peak power load on tired batteries — the very thing that shortens their life — we could all benefit.
One of the main objectives of the project is to even out the peak load across a neighbourhood, and most of the technology needed to achieve this is already available.
Three tanker trucks arrive here on peak production days, loading up with 500 barrels of oil made from 270 tons of turkey guts and 20 tons of pig fat.
Plus, the power draw at that peak load is much higher and the amount of time spent in that mode is much greater than on a standard PC.»
Together the five utilities serve roughly half of Japan's geographic area, including the largest island prefectures, and have peak demand load of roughly 50,000 megawatts.
In non-survivors, viral load is 100-fold higher than that of survivors throughout infection and does not decline after peak.
Exploring the effects of training variables, Bryanton et al. (2012) and Cotter et al. (2013) found that peak knee extensor moments increased with increasing depth (albeit with the same absolute loads).
The jump shrug displays highest peak power outputs, peak velocity, peak joint angular velocities, peak vertical displacement, and peak landing forces with low loads (30 — 40 % of 1RM hang power clean).
Comparing the use of free weight or machine resistance for the power clean performed from the mid-thigh position, Jones et al. (2008) found that 1RM and average power were greater when using free weights but velocity (average and peak) was greater when using the machine loading.
However, Ho et al. (2011) did not find any effect of load on peak barbell velocity across 133 attempts by a single weightlifter.
Similarly, Comfort et al. (2013) compared the power clean performed with 60 — 80 % of 1RM in untrained female athletes and found no differences in peak power output within this range of loads.
Peak GRF was greatest with the highest load: 90 % of 1RM.
In the snatch lift as performed in competition, peak vertical bar velocity can reach 2.1 m / s (Garhammer, 1985; Okada et al. 2011) and the second pull is the fastest phase of the lift (Campos et al. 2006; Harbili, 2012; Korkmaz & Harbili, 2012; Akkuş, 2012; Harbili & Alptekin, 2014; Harbili, 2015), although peak vertical bar velocity is even higher with sub-maximal loads (Hadi et al. 2012).
Although peak velocity is less well - studied, linear barbell velocity reduces with increasing load (Suchomel et al. 2014a), as do the angular velocities of the hip, knee and ankle joints (Suchomel et al. 2014e).
The effects of load and cues to prevent forward knee movement over the toes on peak hip angle are unclear.
The high pull and hang high pull displays the highest peak velocity with low loads (30 % of 1RM hang power clean), the highest force with high loads (80 % of 1RM hang power clean), and the highest peak power with moderate loads (45 % of 1RM hang power clean).
Exploring the effects of training variables, Kellis et al. (2005) found that joint angles differed between relative loads but did not identify how the individual hip, knee and ankle joints differed; however, List et al. (2013) found that increasing load caused peak ankle angle to become more acute, from no load to 25 % of bodyweight, to 50 % of bodyweight.
Wretenberg et al. (1996) similarly observed that peak hip extensor moment was greater when heavier loads were used, although this was likely also a function of differences between powerlifting and Olympic weightlifting styles of squat.
Comparing the back squat with sled pulling, Okkonen and Häkkinen (2013) reported that peak ground reaction forces with 70 % of half squat 1RM were greater than during either block starts or sled pulling with loads of 10 % or 20 % of bodyweight.
Bryanton et al. (2012) found that peak hip extensor moments increased with increasing depth (albeit with the same absolute loads) but Wretenberg et al. (1996) reported that peak hip extensor moments during both powerlifting squats and during Olympic weightlifting - style squats did not differ substantially between deep and parallel versions (deep = maximal knee flexion vs. parallel = posterior of the hamstrings parallel to the ground).
In a further similar study, Suchomel et al. (2015a) found that the vertical displacement during the jump shrug, the peak landing force, and the potential energy of the system at peak vertical displacement were all found at the lowest load used (30 % of 1RM hang power clean).
Wretenberg et al. (1996) found that peak knee extensor moments were lower during powerlifting squats than during Olympic weightlifting - style squats, even though the powerlifting squats involved the use of greater absolute loads; Swinton et al. (2012) reported that peak knee extensor moments were greater in the box squat variation than in either the traditional or powerlifting squat variations, but there was no difference between traditional and powerlifting squats.
They found that peak power, peak bar velocity, and maximum bar displacement occurred with the lowest load tested (40 % of 1RM power clean) while peak force and impulse occurred with the highest load tested (140 % of 1RM power clean).
In a similar study, Suchomel et al. (2013) also found that the jump shrug displayed its greatest peak power output and peak velocity with the lowest load used (30 % of 1RM hang power clean).
Exploring the effects of training variables, Kellis et al. (2005) found that joint angles differed between relative loads but did not identify how the individual hip, knee and ankle joints differed; however, McKean et al. (2010) reported that peak hip angle was more acute with load compared to no load, while both List et al. (2013) and Gomes et al. (2015) reported that peak hip angle became less acute with heavier relative loads.
Also comparing the effect of load but using near - maximal and maximal loads, Harbili & Alptekin (2014) found that when comparing the maximal load to the near - maximal load, there was a reduction in both peak barbell vertical displacement (1.25 vs 1.27 m) and peak vertical barbell velocity (1.72 vs. 1.82 m / s).
Orloff et al. (1997) assessed the effect of load on peak trunk angle and found that there was no effect with increasing load.
Similarly, Wallace et al. (2002) noted that peak knee extensor moment increased between squats with no load to squats with a barbell load equal to 35 % of bodyweight.
However, they did not discern any effect of load on peak force.
Peak GRF is routinely always greatest with the heaviest load (80 — 90 % of 1RM), while peak power output is usually highest at a slightly lower load than the maximal load tested (65 — 80 % of 1RM), and RFD is not generally affected by load to any great extPeak GRF is routinely always greatest with the heaviest load (80 — 90 % of 1RM), while peak power output is usually highest at a slightly lower load than the maximal load tested (65 — 80 % of 1RM), and RFD is not generally affected by load to any great extpeak power output is usually highest at a slightly lower load than the maximal load tested (65 — 80 % of 1RM), and RFD is not generally affected by load to any great extent.
As the periods grow so does the cumulative stress load which is where the athlete does not fully recover from the training during the peak period of training volume for each period and why a recovery period.
For example, when comparing constant load (free weight) and constant resistance (pneumatic machine) bench presses, the constant resistance bench presses involve higher peak velocities, because they allow greater acceleration at the start of the movement (Frost et al. 2008).
Comparing the effect of exercise variation, Santana et al. (2007) explored the peak muscle activity during the bench press and standing 1 arm cable press with similar relative loads.
During bench press throws, Baker et al. (2001) explored the effect of load between 40 — 80 kg (31 -62 % 1RM) on peak power output in highly trained rugby players.
Most other types of external load, including those that add bands and chains to barbells, reduce the size of the peak contraction at long muscle lengths and increase it at shorter muscle lengths.
As expected, mean concentric velocity and peak concentric velocity decreased with increasing relative load (15 — 90 % of 1RM).