A 0.26 kg iron horseshoe that is initially at 787 ◦C is dropped into a bucket...

A 0.440 kg iron horseshoe that is initially at 555°C is dropped into a bucket containing...

A 0.440 kg iron horseshoe that is initially at 555°C is dropped into a bucket containing 18.1 kg of water at 24.0°C. What is the final equilibrium temperature (in °C)? Neglect any heat transfer to or from the surroundings. Do not enter units.

A 0.40-kg iron horseshoe, just forged and very hot is dropped into 1.25 L of water...

A 0.40-kg iron horseshoe, just forged and very hot is dropped into 1.25 L of water in a 0.28-kg iron pot initially at 20.0?C. The value of specific heat for iron is 450 J/kg?C? , and for water is 4186 J/kg?C? If the final equilibrium temperature is 25.0 ?C, Determine the initial temperature of the hot horseshoe.

A hot iron horseshoe ( mass = 0.40kg ) is dropped into 0.00135 m3 of water...

A hot iron horseshoe ( mass = 0.40kg ) is dropped into 0.00135 m3 of water in a .930kg iron pot initially at 20.0 0C. If the final equilibrium temperature is 25.0 0C. What was the initial temperature of the hot horseshoe? ( specific heat of iron = 0.11kcal/kg 0C or 450J/kg 0C

A freshly-forged iron horseshoe, with a mass of 0.399 kg is dropped into a 0.234 kg...

A freshly-forged iron horseshoe, with a mass of 0.399 kg is dropped into a 0.234 kg iron pot which contains 1.27 kg of water at 20.1 oC. After the horseshoe, pot and water reach thermal equilibrium they have a temperature of 29.6 oC. 1. Assuming the pot and the water was in thermal equilibrium before the horseshoe entered the water, calculate the combined amount of heat gained by the pot and water as they cool the horseshoe. 2. Calculate the...

008 A 0.0456 kg ingot of metal is heated to 215◦C and then is dropped into...

008 A 0.0456 kg ingot of metal is heated to 215◦C and then is dropped into a beaker containing 0.415 kg of water initially at 19◦C. If the final equilibrium state of the mixed system is 21.4 ◦C, find the specific heat of the metal. The specific heat of water is 4186 J/kg · ◦ C. Answer in units of J/kg · ◦ C.

A 59-kg iron block and a 20-kg copper block, both initially at 80°C, are dropped into...

A 59-kg iron block and a 20-kg copper block, both initially at 80°C, are dropped into a large lake at 15°C. Thermal equilibrium is established after a while as a result of heat transfer between the blocks and the lake water. Assuming the surroundings to be at 20°C, determine the amount of work that could have been produced if the entire process were executed in a reversible manner. The specific heats of iron and copper are 0.45 kJ/kg·K and 0.386...

An iron boiler of mass 180 kg contains 770 kg of water at 21 ∘C. A...

An iron boiler of mass 180 kg contains 770 kg of water at 21 ∘C. A heater supplies energy at the rate of 58,000 kJ/h. The specific heat of iron is 450 J/kg⋅C∘, the specific heat of water is 4186 J/kg⋅C∘, the heat of vaporization of water is 2260 kJ/kg⋅C∘. Assume that before the water reaches the boiling point, all the heat energy goes into raising the temperature of the iron or the steam, and none goes to the vaporization...

A tank contains 2 kg of water at 25°C. Into this tank, a person dropped a...

A tank contains 2 kg of water at 25°C. Into this tank, a person dropped a 0.9-kg piece of metal that has a temperature of 75°C. What will be the equilibrium temperature of the mixture? Specific heat of metal is 448 J/kg-°C)

A 35.0-g cube of ice, initially at 0.0°C, is dropped into 180.0 g of water in...

A 35.0-g cube of ice, initially at 0.0°C, is dropped into 180.0 g of water in an 70.0-g aluminum container, both initially at 35.0°C. What is the final equilibrium temperature? (Specific heat for aluminum is 900 J/kg⋅°C, the specific heat of water is 4 186 J/kg⋅°C, and Lf = 3.33 × 105 J/kg.) 26.4 °C 17.6 °C 8.79 °C 35.1 °C 30.8 ° C

An iron boiler of mass 180 kg contains 770 kg of water at 21 ∘C. A...

An iron boiler of mass 180 kg contains 770 kg of water at 21 ∘C. A heater supplies energy at the rate of 58,000 kJ/h. The specific heat of iron is 450 J/kg⋅C∘, the specific heat of water is 4186 J/kg⋅C∘, the heat of vaporization of water is 2260 kJ/kg⋅C∘. Assume that before the water reaches the boiling point, all the heat energy goes into raising the temperature of the iron or the steam, and none goes to the vaporization...