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Texte wiki de la nouvelle page, après la modification (new_wikitext) | '<br>Busbar Calculation is a technique to calculate the space required for a structure, to give the answer of the length and width of the structure. It is a combination of bar-outer-height, peak load, peak operating pressure, bus bars (vertical or horizontal), wall thickness, cross section and panel design. There are several ways to calculate size. Some of them are:<br><br><br>The first and the most popular way to perform bus bar calculation is to use DC input resistance as the function of a DC busbar. In this method, all the DC bus bars must be connected to the common terminals. For each busbar, take note of its center-point, its attachment to the center terminal and the distance of its center-point to the outer rings of busbar. Multiply the two results for each of the four edges of each busbar to get the result of its individual center-point and individual attachment to the outer ring. This calculation gives the measurement of the individual bus bar's current capacity and its peak load.<br><br><br>The second way to calculate the size is to use a plot of the cross-section. If you loved this write-up and you would such as to receive more information regarding [https://www.rhibusbar.com/product/electrical_power_bending_busbar.html check it out] kindly check out our own web site. By this method, you can determine the maximum allowable clear span of any structure. You can calculate the maximum clear span by dividing the total area by its maximum clear span. The peak load is then derived from this function of cross-section. The current capacity function is then used to determine the peak-load ratings of the structures.<br><br><br>Third way to calculate the size is to use single phase AC input resistance function. This method is applicable only for single phase AC input. The calculation is done by connecting one terminal to the other at a single point. The terminals will be selected in order to produce a maximum quantity of current. The result of single phase AC input resistance function is then divided by the area of each bus wire to get the value of the individual conductor connection.<br><br><br>Fourth way to calculate the size is by single mode and double mode bus bar sizing. In single mode sizing, a parallel-wire is connected between the top and bottom of the bus bar. The bottom bus wire will be connected to the bottom most terminal while top wire will be connected to the next most terminal. The application of this method is mostly needed for electrical panel design. For dual mode sizing, two parallel wires will be connected between the top and bottom of the bus bar.<br><br><br>The last way to calculate bus bar size is by solving the non-algebraic equations through quadratic formula. The solution is usually obtained by finding the solutions of first-order and second-order polynomial equations. You can find more details about this method in previous articles. The solutions of non algebraic equations may be used to solve problems like force field, tensors, volume, phase, potential, derivative, integral functions and so on. This is also one of the methods that you may use in your industrial mechanical engineering projects.<br>' |
