Veq = 133000*(Condensate specific gr/Mol wt of condensate) in SCF/STB
Where,
Mol wt of condensate = 6084/(API-5.9)
LPG contains propane (C3H8) and butane (C4H10)
Several small volumes is more effective.
Yes
Dividing weight by volume . W/v - kg/m3.
The formula for volume of a liquid in the pipe is V=(pi/4)D2 (L)
Condensate yield refers to the amount of liquid (condensate) produced from natural gas or oil during processing and separation. It is commonly expressed as the volume or percentage of condensate recovered from the raw natural gas or oil. Achieving a high condensate yield is important for maximizing the value of the produced hydrocarbons.
Area and volume are not equivalent, so you cannot convert one to the other.
A Bose-Einstein condensate does have volume, but the volume is very small. All the atoms in a Bose-Einstein condensate are superimposed on each other, so no matter how many you have, the volume is that of a single atom.
Length and volume are not equivalent measurements. Length is a two dimensional measurement while volume is a three dimensional measurement.
CGR, or Condensate Gas ratio, is the ratio of condensate liquid volume divided by dry gas volume. The field unit is bbl/MMscf. The inverse of CGR is GOR (Gas Oil ratio), although solution GOR is the amount of gas dissolved in 1 bbl of oil, while CGR is an indicator of how much condensate will drop out of 1 MMscf of gas.
The unit of liquid condensate is typically measured in barrels (bbl) or gallons (gal). These units are commonly used to quantify the volume of liquid condensate produced or processed in the oil and gas industry.
1 cubic meter is equivalent to 1000 litres is the formula for the conversion.
You can't convert that. Hectoliter, and liter, are units of volume; meter is a unit of length. You might, however, convert hectoliters to CUBIC meters.
That's a unit of volume. cc (cubic centimeters) is the same as milliliter. If you want to convert that to liters, you can divide by 1000.
Liters IS volume - there is nothing to convert.
The six natural forms often refer to the fundamental states of matter: solid, liquid, gas, plasma, Bose-Einstein condensate, and fermionic condensate. Each state has distinct properties based on particle arrangement and energy levels. Solids have a fixed shape and volume, liquids have a fixed volume but take the shape of their container, gases fill their container, and plasma consists of ionized gases. The latter two forms, Bose-Einstein and fermionic condensates, occur under extreme conditions, such as near absolute zero.
Matter can exist in three forms: solid, liquid, and gas. Solids have a fixed shape and volume, liquids have a fixed volume but take the shape of their container, and gases have neither a fixed shape nor volume.