What amount of energy is required to change a spherical drop of water with a diameter...

Pressurized Water is heated in a thin tube with a diameter of 60 mm. water enters...

Pressurized Water is heated in a thin tube with a diameter of 60 mm. water enters with a mass flow rate of 0.01 kg/s and an inlet temperature of 20°C. a uniform heat flux of 2000 W/m2 is applied to the tube. What is the required length of the tube to obtain an exit temperature of 80°C for the water? If the water reaches 80°C at the outlet, what is the surface temperature of the tube at the outlet?

(a) What is the pressure drop due to the Bernoulli effect as water goes into a...

(a) What is the pressure drop due to the Bernoulli effect as water goes into a 2.70-cm-diameter nozzle from a 8.90-cm-diameter fire hose while carrying a flow of 41.0 L/s? N/m2 (b) To what maximum height above the nozzle can this water rise? (The actual height will be significantly smaller due to air resistance.) m

(a) What is the pressure drop due to the Bernoulli effect as water goes into a...

(a) What is the pressure drop due to the Bernoulli effect as water goes into a 2.70-cm-diameter nozzle from a 8.90-cm-diameter fire hose while carrying a flow of 41.0 L/s? N/m2 (b) To what maximum height above the nozzle can this water rise? (The actual height will be significantly smaller due to air resistance.) m

What is the pressure drop (in N/m2) due to the Bernoulli effect as water goes into...

What is the pressure drop (in N/m2) due to the Bernoulli effect as water goes into a 2.70 cm diameter nozzle from a 8.90 cm diameter fire hose while carrying a flow of 35.0 L/s?   N/m2 (b) To what maximum height (in m) above the nozzle can this water rise? (The actual height will be significantly smaller due to air resistance.) m

(a) What is the pressure drop (in N/m2) due to the Bernoulli effect as water goes...

(a) What is the pressure drop (in N/m2) due to the Bernoulli effect as water goes into a 3.50 cm diameter nozzle from a 9.10 cm diameter fire hose while carrying a flow of 34.0 L/s? Answer is in unit N/m2 (b) To what maximum height (in m) above the nozzle can this water rise? (The actual height will be significantly smaller due to air resistance.) Answer is in unit m

Calculate the amount of heat energy required to change 0.173 kg of ice at a temperature...

Calculate the amount of heat energy required to change 0.173 kg of ice at a temperature of -35 �C to steam at a temperature of 160 �C. (specific heat capacities of ice, water and steam are 2090, 4180, 2010 J ⁄ kg ⁄ �C respectively. Latent heat of fusion and vaporization of water are 3.34e5, 2.26e6 J ⁄ kg respectively.)

A spherical steel ball bearing has a diameter of 2.540 cm at 25°C. (a) What is...

A spherical steel ball bearing has a diameter of 2.540 cm at 25°C. (a) What is its diameter when its temperature is raised to 100°C? (b) What temperature change is required to increase its volume by 1%?

A 3-m-internal-diameter spherical tank made of 1-cm-thick stainless steel is used to store iced water at...

A 3-m-internal-diameter spherical tank made of 1-cm-thick stainless steel is used to store iced water at 0°C. The tank is located outdoors at 18°C. Assume the entire steel tank to be at 0°C and thus the thermal resistance of the tank to be negligible. The heat of fusion of water at atmospheric pressure is hif = 333.7 kJ/kg. The emissivity of the outer surface of the tank is 0.75, and the convection heat transfer coefficient on the outer surface can...

A water drop slung onto a skillet with a temperature between 100°C and 200°C will remain...

A water drop slung onto a skillet with a temperature between 100°C and 200°C will remain a liquid for about 1 second. However, if the skillet is much hotter the drop can last several minutes. This is due to the Leidenfrost Effect, named after an early investigator (circa 1756). The longer lifetime is due to the support of a thin layer of air and water vapor that separates the drop from the metal (by a distance L, as shown in...

Assuming that all the energy of the water is converted to heat, calculate the temperature rise...

Assuming that all the energy of the water is converted to heat, calculate the temperature rise of the water in degrees Celsius after falling over California'a Yosemite Falls, a distance of 739 m. Potential energy of the water at the top of the falls is equal to mass of the water times the acceleration due to gravity times the height. 1 kg m2/s2 is equal to _____ Joule. Assume 1.00 kg of water falling over Yosemite. The change in potential...