9144
The temperature of the body is usually from 36.7 to 37.9 degrees celsius
To convert one into the other. Temperature Fahrenheit = Temperature Celsius(1.80) + 32
Temperature Fahrenheit = Temperature Celsius(1.80) + 32 Temperature Fahrenheit = (37.8 degrees Celsius) * (1.80) + 32 Temperature Fahrenheit = 100.04 degrees -------------------------------------------------------
The temperature in the Earth's mantle can be anywhere from 500 to 900 degrees Celsius. Closer to the core of the Earth, the temperature can reach 4,000 degrees Celsius.
-89 Celsius -89 Celsius -89 Celsius
0.008 ?? 0.008 * 9000 barrels = 72 + 9000 barrels = 9072 barrels net amount loaded ------------------------------------------------
The coefficient of thermal expansion of ethanol at 20 degrees Celsius, in volumetric terms, is 750*10-6 per Kelvin.The coefficient of thermal expansion of ethanol at 20 degrees Celsius, in volumetric terms, is 750*10-6 per Kelvin.The coefficient of thermal expansion of ethanol at 20 degrees Celsius, in volumetric terms, is 750*10-6 per Kelvin.The coefficient of thermal expansion of ethanol at 20 degrees Celsius, in volumetric terms, is 750*10-6 per Kelvin.
-39 degrees celsius to 450 degrees celsius
120×10^-6
temperature coefficient =10 degree celsius..
The unit of temperature coefficient of resistance is ohm per ohm per degree Celsius or say resistance per resistance per degree Celsius.
Difference in volume = (initial volume) (coefficient of volume expansion of water) (difference in temperature) coefficient of volume expansion of water=0.0002ml/degree celsius (not sure about the value. Better get help from a teacher.)
specific gravity of gasoline at 104 celsius
It depends on how significant the temperature variation is. Jet fuel has a coefficient of thermal expansion of 0.00099/C. That means that for every 10 degree Celsius rise in temperature the volume will increase by almost 1%.
The critical temperature of gasoline is the temperature at which it becomes combustible and varies according to the pressure the gas is under. On average this temperature is 241 degrees Celsius.
dL/dT = αL*L, where L is the length of the steel, T is temperature, and αL is the linear thermal expansion coefficient which for steel is about 11.0 to 13.0. That is possibly the easiest differential equation in history: (1/L)dL = (αL)dT ln(L) = αLT L = eαLT
The clearest answer I've heard to date is that the coefficient is 0.00046 per degree Fahrenheit. That is to say that for every degree rise in temperature your volume will go up that amount. The math works like this, say you have a temperature rise from 60 degrees f to 84 f over the course of a day and a tank with 100 gallons of diesel in it. Multiply the coefficient by the number of degrees temp rise (24 x 0.00046=0.01104) then multiply that answer by the total number of gallons you started with to get the number of gallons increase in the tank when the diesel warmed up to 84 degrees (0.01104 x 100=1.104 gal.) Remember the liquid itself has to rise in temperature and it may take a long time to do but this is a handy way to figure the amount of room to leave in a tank for expansion.