The utilization factor is dependent on the anode design, particularly on its dimensions and the location of anode cores. Table 6.15 presents anode utilization factors, based on DNV RP B401, that are used for design calculations. According to BS, an anode utilization factor of 0.90 for the long, slender, stand-off type shall be considered in design.

 · Bookmark this question. Show activity on this post. I am learning the basics for queuing theory for a M/M/1 queue. One thing I do not understand is to do with utilization factor ρ. Assuming that: λ = arrival rate, exponentially distributed. μ = service rate, exponentially distributed. ρ = utilization factor. Therefore ρ = λ μ < 1.

 · Resource utilization = busy time / available time. This will give you a value that can be then changed to a percentage of how much of your team's time is spent working. But even this simple formula can get complicated as you begin to question the figures to use in the equation.

 · Utilization calculation example. 1 billable team member of a consulting firm worked on a project for 1 year. This represents 1,450 hours billed. Assuming 52 working weeks and 10 holidays in 1 year (2,000 hours) the annual employee utilization in this case is 72.5%. Take a look at average employee utilization rates by industry, as listed by ...

 · SECTION 3: AIRCRAFT CAPACITY AND UTILIZATION FACTORS 3.1 INTRODUCTION Aircraft capacity and utilization factors apply primarily to the evaluation of FAA investment and regulatory programs that affect time spent in air transportation, system capacity and aircraft utilization. The utilization of available capacity affects the benefits and costs that

 · Transformer Utilization Factor (TUF) is defined as the ratio of DC power output of a rectifier to the effective Transformer VA rating used in the same rectifier. Effective VA Rating of transformer is the average of primary and …

The Utilization Factor of the electrical energy formula is defined as the ratio between the total lumens reaching the working plane and the total lumens emitting from the source and is represented as UF = L r / L e or Utilization Factor = Lumen reaching working plane / Lumen emitting from source.The Lumen reaching working plane is defined as the amount of luminous …

 · Utilization Factor = The time that a equipment is in use./. The total time that it could be in use. Example: The motor may only be used for eight hours a day, 50 weeks a year. The hours of operation would then be 2000 hours, and the motor Utilization factor for a base of 8760 hours per year would be 2000/8760 = 22.83%.

To cope with this sort of scenario, the use of a Power Utilization Factor (PUF), in addition to the usual Power Factor and Cos Phi, is suggested on analytical and experimental grounds. The use of ...

 · Floor Multiplying Factor MF .90 5 Coefficient of Utilization * CU .56 *Coefficient of Utilization from manufacturers literature or Page 23-31 IES Handbook Number of Fixtures = 50 FC x 25.5 Room Length x 26.5 Room Width .56 C.U. x 4 Lamps x 3150 Lumens x .90 M.F. x .85 LLD x .77 x LDD x .95 RSDD = 8.3 Fixtures Use 8 Fixtures

 · The basic formula is pretty simple: it's the number of billable hours divided by the total number of available hours (x 100). So, if an employee billed for 32 hours from a 40-hour week, they would have a utilization rate of 80%. There are actually several different ways you can calculate utilization rates depending on whether you want to ...

Utilization factor is affected by the size of the room. The larger the room, the smaller the utilization factor for each light. Take into account the size of the room and the brightness of each light you consider installing in the room, to ensure there is adequate lighting.

 · Utilization = Billable Hours / Total Hours Available. So let's say John works Monday through Friday for a total of 40 hours a week. Every day, he bills 5 hours to the client, or 25 hours a week total. When his time is put into the handy formula (25/40 = .625), we see that his Utilization Rate is 62.5%.

 · Hi, Efficiency is = (actual output/Effective capacity), effective capacity would be your benchmark or target set for that task. Utilization is = (actual output/designed capacity), designed capacity is the target which can be achieved under ideal condition for e.g you have 8 hr/day to work, 8 hrs would be your designed capacity but in real time you are working 7 hrs (excluding …

 · Utilization Factor or Co-efficient of utilization. It may be defined as "the ratio of total lumens received on the working plane to the total lumens emitted by the light source". i.e. It may be defined as "the ratio of illumination under normal working condition to the illumination when everything is clean or new" i.e.

 · The utilization factor table and a few simple formulas allow us to calculate the number of fittings required for any room. Step 1: Understand the utilization factor table that is available on most fittings. UTILIZATION FACTOR TABLE (for 2x36 bare batten) LOR: 88.1%. SHR NOM 1.75: 1.0. Disregard SHR MAX. Reflectance. Room Index (K)

If P n is the equipment rated power and f u the annual utilization factor, the number of equivalent hours operating at full load is 8760 f u, so that the equipment production will be 8760 P n f u, for example, in kWh/year.If I is the investment required, the investment cost per product unit is z P = a I/(8760 P n f u).Calling z Pu the investment and maintenance equipment cost per product …

The Equipment Utilization Factor formula is defined as the amount of energy used divided by the maximum possible to be used is calculated using Equipment utilization factor = SE when SC fully utilized / Total no of SE.To calculate Equipment Utilization Factor, you need SE when SC fully utilized (S) & Total no of SE (T.SE).With our tool, you need to enter the respective value for …

These two factors affect the capacity utilization factor as well. According to the reports from MNRE in 2013, the average capacity utilization factor of solar PV plants in India is in the range of 15-19%.In particular, solar plants in Rajasthan and Telangana have recorded the highest capacity utilization factor; it being in the range of 20%.The ...

Utilization Rate Calculation Example. Suppose an employee is paid on the expectation of logging 40 hours of work per week. If that employee billed clients for 34 of those hours, the utilization rate for the week is 85%. Utilization Rate = 34 Hours ÷ 40 Hours = .85, or 85%. Therefore, if that employee were to hypothetically work 1,800 hours (i ...

See also: Fast Fission Factor See also: Resonance Escape Probability See also: Thermal Utilization Factor See also: Reproduction Factor The infinite multiplication factor (k ∞) may be expressed mathematically in terms of these …

 · Utilization Factor Structural Design. The design is unacceptable if the degree of utilization is > . Traditional factor of safety against piping. Factor of safety on hydraulic gradient is F =-= 3.38 w. ©0 The degree of utilization using expression 2.9 (a) is close to , whereas using 2.9 (b) it is less than 50%.

 · The utilization factor or use factor is the ratio of the time that a piece of equipment is in use to the total time that it could be in use. It is often averaged over time in. This is currently done on a capacity basis working on a focus factor of 60%. Teams that use velocity for planning typically base velocity ion the.

 · Utilization factor is a metric for power plants that describes how close the plant is operating to full capacity. For hydropower, utilization factor can be …

 · Transformer Utilization Factor (TUF) is defined as the ratio of DC power output of a rectifier to the effective Transformer VA rating used in the …

Thermal Utilization Factor. Obviously, the neutrons that escape the resonance absorption and remain in the core will be thermalized.In thermal reactors, these neutrons continue to diffuse throughout the reactor until they are absorbed. But there are many materials in the reactor core in which these neutrons may be absorbed. The thermal utilization factor, f, is the fraction of the …