A flow rate value greater than 1.00 indicates that the amount of material passing through a certain point is more than the total available amount, which is not physically possible. It suggests a miscalculation or error in measurement, as the flow rate should always be within the constraints of the system's capacity.
The coefficient of contraction in an experiment may be greater than the theoretical value due to factors such as flow imperfections, wall roughness, or turbulence in the flow. These factors can lead to additional energy losses and create a greater contraction in the flow compared to the ideal theoretical case. Experimental conditions and inaccuracies in measurements can also contribute to discrepancies between the observed and theoretical values of the coefficient of contraction.
Current i.e.rate of flow of charge when stops flowing in a circuit then fuse does not blows out. The only work of fuse is to blow away when the current starts flowing greater in magnitude than the rated current value.
Pressure loss is typically larger in gas-liquid flow compared to liquid flow due to the compressibility of gas. Gas-liquid flow can experience significant pressure drops due to the expansion and compression of gas bubbles within the liquid, leading to greater friction losses.
A substance with molecules that have greater freedom of movement enabling them to flow is considered a liquid. In liquids, the molecules have enough energy to move past each other but still remain relatively close together. This allows the substance to take the shape of its container.
Pulmonary surfactants reduce surface tension in alveoli, preventing them from collapsing and making it easier for air to flow in and out of the lungs. Without surfactants, smaller alveoli would have a higher surface tension, leading to greater pressure inside them compared to larger alveoli. As a result, air would tend to flow from smaller alveoli to larger ones to equalize pressure, potentially causing problems with lung function.
The coefficient of contraction in an experiment may be greater than the theoretical value due to factors such as flow imperfections, wall roughness, or turbulence in the flow. These factors can lead to additional energy losses and create a greater contraction in the flow compared to the ideal theoretical case. Experimental conditions and inaccuracies in measurements can also contribute to discrepancies between the observed and theoretical values of the coefficient of contraction.
Yes, the R-value of insulation indicates its resistance to heat flow. The higher the R-value, the greater the insulation's ability to resist heat transfer, making it more effective at insulating a building.
by its R-value, with a higher R-value indicating greater resistance to heat flow.
The cash flow is different in different countries because of the econmoy. Depending the value of the currency some countries would greater cash flow compare to poor countries.
That is a NO NO. You should never clean the mass air flow sensor it will mess it up.
The higher the R-value, the better the insulation. Therefore, a material with an R38 insulation value will have less heat loss compared to a material with an R30 insulation value since it provides greater resistance to heat flow.
if leakages are greater than injection the circular flow will be in disequilibrium because more money is leaving the circular flow
Current i.e.rate of flow of charge when stops flowing in a circuit then fuse does not blows out. The only work of fuse is to blow away when the current starts flowing greater in magnitude than the rated current value.
Never.A program should handle exceptions, but should NEVER USE exceptions to control program flow.
no
yes the R-value does indicate resistance to heat flow
Greater value resistor will absorb more voltage than smaller value. The more voltage absorb with same value current flow, the larger body mass resistor will require. Body size depends on type of resistor (material resistor is made of).