It will pull off your shoulder as you advance, no need to flip the load onto your shoulder as with a flat load. Personally I think the triple layer load is the most usefull
A kva load in the text that you use it is the same as a wattage load. To find your answer just total up all of your appliance wattage's, portable and hard wired, in the unit and this will give you an idea of what you have for a load.
Load current is related to load resistance by an inverse relationship. The load current increases linearly as load resistance decreases. Remember, the less resistance, the more current.
In case of grounded load load is grounded and voltage is measured across it. while in case of floating load load is not grounded instead it is connected in feedback circuit.
A man with a load jumps from a high building. What will be the load experienced by him?
Hope this helpsAn "OFF-Load tap transformer" can only have it's tap adjusted when it is De-energized,while the "On-Load tap transformer" can adjust its tap under load conditions.Kind RegardsHammad KhanUniversity of Western AustraliaAnswerAn 'off load' transformer is one whose secondary is open circuited, and not supplying a load. An 'on load' (not 'load') transformer is one that is connected to a load.
Mechanical Advantage = Effort/Load
Mechanical advantage=load/effort
Mechanical Advantage;The ratio of load and effort is called mechanical advantage of any machine.Mathematical Formula Of Mechanical AdvantageMechanical Advantage = Load / EffortUnit Of Mechanical AdvantageAs mechanical advantage is the ratio of two forces, therefore it has no unit.
the load and fulcrum
The mechanical advantage of a lever is that it can lift a 100N load with an input of 20N is calculated as is 5. In this case, the effort is divided by the load.
4Explanationfor a lever,effort * effort arm = load *load armso by re arranging above equation,load/effort = effort arm/load armNow, as load/effort is called mechanical advantage so,mechanical advantage = effort arm/load armAs total length of rod is 2 m out of which 1.6 m is effort arm so remaining 0.4 m would be load arm. thus on putting values in the above equation, we getmechanical advantage = 1.6/0.4 = 4
The load is the weight and the effort is the movment. The effort is the force applied, and load divided by effort is mechanical advantage.
You get greater mechanical advantage the closer the fulcrum is to the resistance (load).
The 'ideal' mechanical advantage is length of the effort arm/length of the load arm .
it is d ratio of the load to the effort applied to move the load if mechanical advantage>1(ie L/E >1), the machine acts as a force multiplier otherwise as a machine to gain speed mechanical advantage is abbreviated as M.A.
It is calculated by dividing the load by the effort.
It is calculated by dividing the load by the effort.