Question

In a copper vessel with a temperature of t1 = 350 C, m2 = 600 g...

In a copper vessel with a temperature of t1 = 350 C, m2 = 600 g of ice
with a temperature of t1 = 10 C. After some time a
Mixture of m3 = 550 g ice and m4 = 50 g water. Find the mass of the vessel m1.
In the solution, neglect the heat exchange between the vessel and
environment.
The specific heat capacity of copper is cK = 0:39 kJ/(kg*K). The specific
Heat capacity of the ice is cE = 2:1 kJ/(kg*K). The specific heat of fusion of the
Ice is Ls = 333 kJ/(kg)

Translated with www.DeepL.com/Translator (free version)

In a copper vessel with a temperature of t1 = 350 C, m2 = 600 g of ice
with a temperature of t1 = 10 C. After some time a
Mixture of m3 = 550 g ice and m4 = 50 g water. Find the mass of the vessel m1.
In the solution, neglect the heat exchange between the vessel and
environment.
The specific heat capacity of copper is cK = 0:39 kJ/(kg*K). The specific
Heat capacity of the ice is cE = 2:1 kJ/(kg*K). The specific heat of fusion of the
Ice is Ls = 333 kJ/(kg)

Homework Answers

Know the answer?
Your Answer:

Post as a guest

Your Name:

What's your source?

Earn Coins

Coins can be redeemed for fabulous gifts.

Not the answer you're looking for?
Ask your own homework help question
Similar Questions
A 25.0-g glass tumbler contains 200 mL of water at 24.0ºC. If two 15.0-g ice cubes,...
A 25.0-g glass tumbler contains 200 mL of water at 24.0ºC. If two 15.0-g ice cubes, each at a temperature of –3.00ºC, are dropped into the tumbler, what is the final temperature of the drink? Neglect any heat transfer between the tumbler and the room. (Specific heat of water and ice are 4.186 kJ/(kg K) and 2.05 kJ/(kg K), respectively. The latent heat of fusion of water is 333.5 kJ/kg. The specific heat of glass is 0.840 kJ/(kg K )....
A well-insulated 0.2kg copper bowl contains 0.10kg of ice, both at −10◦ C. A very hot...
A well-insulated 0.2kg copper bowl contains 0.10kg of ice, both at −10◦ C. A very hot 0.35kg copper cylinder is dropped into it and the lid quickly closed. The final temperature of the system is 100◦C, with 5g of steam in the container. (a) How much heat was transferred to the water (in all phases); (b) How much to the bowl? (c) What must have been the original temperature of the cylinder? The specific heat of copper is 386 J/kg·K....
A 10.g cube of copper at a temperature T1 is placed in an insulated cup containing...
A 10.g cube of copper at a temperature T1 is placed in an insulated cup containing 10.g of water at a temperature T2. If T1>T2, which of the following is true of the system when it has attained thermal equillibrium? (The specific heat of copper is 0.385 J/g degrees C) and the specific heat of water is 4.184 J/g degrees C) A. The temperature of the copper changed more than the temperature of the water. B. The temperature of the...
An insulated Thermos contains 115 g of water at 78.7 ˚C. You put in a 10.0...
An insulated Thermos contains 115 g of water at 78.7 ˚C. You put in a 10.0 g ice cube at 0.00 ˚C to form a system of ice + original water. The specific heat of liquid water is 4190 J/kg•K; and the heat of fusion of water is 333 kJ/kg. What is the net entropy change of the system from then until the system reaches the final (equilibrium) temperature?
An insulated Thermos contains 113 g of water at 77.3 ˚C. You put in a 10.3...
An insulated Thermos contains 113 g of water at 77.3 ˚C. You put in a 10.3 g ice cube at 0.00 ˚C to form a system of ice + original water. The specific heat of liquid water is 4190 J/kg•K; and the heat of fusion of water is 333 kJ/kg. What is the net entropy change of the system from then until the system reaches the final (equilibrium) temperature?
An insulated Thermos contains 119 g of water at 75.1 ˚C. You put in a 9.16...
An insulated Thermos contains 119 g of water at 75.1 ˚C. You put in a 9.16 g ice cube at 0.00 ˚C to form a system of ice + original water. The specific heat of liquid water is 4190 J/kg•K; and the heat of fusion of water is 333 kJ/kg. What is the net entropy change of the system from then until the system reaches the final (equilibrium) temperature?
An insulated Thermos contains 141 g of water at 72.1 ˚C. You put in a 6.60...
An insulated Thermos contains 141 g of water at 72.1 ˚C. You put in a 6.60 g ice cube at 0.00 ˚C to form a system of ice + original water. The specific heat of liquid water is 4190 J/kg•K; and the heat of fusion of water is 333 kJ/kg. What is the net entropy change of the system from then until the system reaches the final (equilibrium) temperature?
A cup of warm water (0.5 kg at 25*C) is poured into a large vat of...
A cup of warm water (0.5 kg at 25*C) is poured into a large vat of liquid nitrogen at 77K. The mixture is thermally insulated from the surrounding room. The following table of data may be relevant for this problem (all atmospheric pressure): Nitrogen Water Freezing Point(K) Boiling Point (K) 63 77 273 373 Specific Heat Capacity (J/kg.K) 1040 4186(water) 2108(ice) Latent Heat of Fusion(KJ/kg) Latent Heat of Vaporization (kJ/kg) 25.7 200 333 2260 (A) What will the final temperature...
A 200 g of copper, initially at 300o C, is dropped into a 350 g of...
A 200 g of copper, initially at 300o C, is dropped into a 350 g of water contained in a 355 g aluminum calorimeter; the water and the calorimeter are initially 15o C. If 25 g iron stirrer is used to bring the mixture into thermal equilibrium, what is the final temperature of the system? ( Assume that the stirrer is initially at 15o C.) Specific heat of copper and aluminum are 0.092 cal/g oC and 0.215 cal/g oC respectively....
A copper cylinder with a mass of 125 g and temperature of 345°C is cooled by...
A copper cylinder with a mass of 125 g and temperature of 345°C is cooled by dropping it into a glass beaker containing 565 g of water initially at 20.0°C. The mass of the beaker is 50.0 g and the specific heat of the glass is 840 J/kg∙K. What is the final equilibrium temperature of the system, assuming the cooling takes place very quickly, so that no energy is lost to the air? The specific heat of copper is 385...
ADVERTISEMENT
Need Online Homework Help?

Get Answers For Free
Most questions answered within 1 hours.

Ask a Question
ADVERTISEMENT