GA double-pipe heat exchanger willbe used to cool a hot stream (ininner pipe, ID 2.067 in, OD=2.375 in) from 350°F to 250°F byheating a cold stream (in annulus,ID 4.05 in) from 80°F to 120°F. Ifthe heat-transfer coefficients are hi= 200 and ho=350 Btu/h. ft² °F,calculate the wall temperature ofinner pipe.=

The objective of the question is to calculate the wall temperature of the inner pipe in a…

Answered: G A double-pipe heat exchanger will be…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

See similar textbooks

Similar questions

A liquid food flows in the inner pipe (internal diameter-8 cm) of a double-pipe heat exchanger. The liquid food (p=1200 kg/m and C,-4 kJ/kgK) flows at 0.055 m/min and enters the heat exchanger at 6°C and exits at 38°C. In the annular section, water at 96°C enters the heat exchanger and flows countercurrently at an average flow rate of 1 kg/s (average Cp= 4.18 kJ/kgK). a) Sketch a graph showing the temperature profile of the heating water and quid food through the heat exchanger. Clearly label the two streams and draw arrows to indicate the flow directions of liquid food and water. i) ii) Calculate the mass flow rate (kg/s) of the liquid food. ii) Me sure the temperature (°C) of the exiting water stream. iv) Calculate the log-mean temperature difference for this system. Estimate the length (m) of this pipe heat exchanger that needs to be constructed in order to achieve an overall heat transfer coefficient of 2.5 W/m2K.
(2.23) A finned heat exchanger tube is made of aluminum alloy (k = 186 W/m · K) and contains 125 annular fins per meter of tube length. The bare tube between fins has an OD of 50 mm. The fins are 4 mm thick and extend 15 mm beyond the external surface of the tube. The outer surface of the tube will be at 200°C and the tube will be exposed to a fluid at 20°C with a heat-transfer coefficient of 40 W/m2 · K. Calculate: (a) The rate of heat transfer per meter of tube length for a plain (un-finned) tube. (b) The fin efficiency. (c) The fin and prime surface areas per meter of tube length. (d) The weighted efficiency of the finned surface. (e) The rate of heat transfer per meter of tube length for a finned tube. (f) If the cost per unit length of finned tubing is 25% greater than for plain tubing, determine whether plain or finned tubing is more economical for this service. %3D Ans. (a) 1130 W. (b) 98.6%. (c) 0.8946 m? and 0.07854 m². (d) 98.7%. (e) 6920 W.
Consider a flow of water in a cylinder maintained at constant temperature of 1000 C, the diameter of the cylinder is 50 mm and the length of the tube is 6m. The inlet and the outlet temperature of the water is Ti = 150 C and T0 = 570 C . Find the average heat transfer coefficient associated with the flow of water . Mass flow rate is 0.25 Kg/ s and Cp = 4.178 KJ/Kg.K
Hot gas enters a finned-tube, crossflow heat exchanger at 300 °C and exits at 100 °C. Assume that both fluids are unmixed. The gas is used to heat pressurized water flowing at 1 kg/s from 35 °C to 125 °C. Assume constant properties and use 1000 J/kg K and 4197 J/kg K as the specific heat of the gas and the water, respectively. The overall heat transfer coefficient, based on the gas-side surface area is U₁ = 100 W/m² K. Please determine the required gas side surface area (Aŉ), using the NTU method. Repeat the problem using the LMTD method. Compare your results by quantifying the difference between the two methods with a percent difference and write an observation/conclusion for this result.
I need the solution in hand writing
The hot gas temperature in a heat exchanger is 350 deg C (ho=220 W/m2-K). What is the surface temperature on the wall if the heat transferred is 1500 W/m2? Select the correct response: 358 deg C 350 deg C 338 deg C 343 deg C
A heat exchanger is to be designed to condense 8 kg/sec of an organic liquid (tsat=80°C, hfg=600 KJ/kg) with cooling water available at 15°C and at a flow rate of 60 kg/sec. The overall heat transfer coefficient is 480 W/m2 -°C calculate: a) The number of tubes required. The tubes are to be of 25 mm outer diameter, 2 mm thickness and 4.85 m length b) The number of tube passes. The velocity of the cooling water is not to exceed 2 m/sec.
Hot exhaust gases are used in a finned-tube cross-flow heat exchanger to heat 2.5 kg/s of water from 35 to 85-C. The gases [cp = 1.09 kJ/kg . °C] enter at 200 and leave at 93°C. The overall heat-transfer coefficient is 180 W/m2 • °C. Calculate the area of the heat exchanger using the LMTD approach.
Q2 a) Consider heat transfer to oil flow inside a copper pipe. Is the pipe length affecting the heat transfer rate into the oil? Briefly explain. b) Used engine oil can be recycled by a patented reprocessing system. Suppose that such a system includes a process during which engine oil flows through a 1-cm-internal diameter, 0.02-cm- wall copper tube at the rate of 0.05 kg/s. The oil enters at 35°C and is to be heated to 45°C by atmospheric-pressure steam condensing on the outside, as shown in figure given below. i) ii) iii) Determine the condensing steam temperature at 1 atm, T. [°C]. Calculate the convection heat transfer coefficient for the oil inside the pipe, [W/m'.K]. Calculate the rate of heat transfer rate into the oil, [kW], and, determine the length of the tube required. iv) Condensing steam Ct lam Oil in 35°C Oil out 0.05 kg/s I em 45°C 0.02 cm Copper tube L = ?
4. The following heat exchanger uses 10 kg/s of hot air to heat and boil liquid water into saturated steam at 500 kPa. (a) Find the steam flow (kg/s) (b) Determine whether the process is allowed by the second law (Answer: It is not!) (c) On the surface, the process looks OK as Tair>Twater at both the inlet and outlet. You should be able to see the problem if you sketch the air and the water temperature profiles as you move left to right through the exchanger. (Hints: The air will be essentially a straight line, while the water will not. For the water, think about what happens when it is changing phase.) This is called a pinch point violation, and it is a very important design consideration in advanced combined cycle systems and in nuclear power plants. Air 100 kPa 160°C 10 kg/s Saturated Vapor 500 kPa Air: 160°C Steam: 151.8°C Q Air 100 kPa 30°C Liquid Water 500 kPa, 20°C Air: 30°C Water: 20°C
b) A shell and tube heat exchanger is constructed of a copper having inner tube of inner diameter 2.8 cm and outer diameter D, = 4.0 cm and an outer tube of diameter 5.2 cm. The length of the tube is 10 m. The convection heat transfer coefficient is given to be h = 750 W /M²°C on the inner surface of the tube and h, = 1350 W/m2°C on the outer surface. Determine | i. The thermal resistance of the heat exchanger ii. The overall heat transfer coefficients U; and U, based on the inner and outer surface areas of the tube, respectively.
copper determine the overall heat transfer coefficient of a condenser formed of pipe when the fluid-side heat-transfer coefficient is 2000 W/m². °C and the heat-transfer coefficient on the refrigerant side is 1200 W/m². °C. The pipe has an outside diameter of 25.4 mm and an inside diameter of 19.8 mm. The thermal conductivity of steel is (410) W/m °C.

SEE MORE QUESTIONS

Recommended textbooks for you

Elements Of Electromagnetics

Mechanical Engineering

ISBN:

9780190698614

Author:

Sadiku, Matthew N. O.

Publisher:

Oxford University Press

Mechanics of Materials (10th Edition)

Mechanical Engineering

ISBN:

9780134319650

Author:

Russell C. Hibbeler

Publisher:

PEARSON

Thermodynamics: An Engineering Approach

Mechanical Engineering

ISBN:

9781259822674

Author:

Yunus A. Cengel Dr., Michael A. Boles

Publisher:

McGraw-Hill Education

Elements Of Electromagnetics

Mechanical Engineering

ISBN:

9780190698614

Author:

Sadiku, Matthew N. O.

Publisher:

Oxford University Press

Mechanics of Materials (10th Edition)

Mechanical Engineering

ISBN:

9780134319650

Author:

Russell C. Hibbeler

Publisher:

PEARSON

Thermodynamics: An Engineering Approach

Mechanical Engineering

ISBN:

9781259822674

Author:

Yunus A. Cengel Dr., Michael A. Boles

Publisher:

McGraw-Hill Education

Control Systems Engineering

Mechanical Engineering

ISBN:

9781118170519

Author:

Norman S. Nise

Publisher:

WILEY

Mechanics of Materials (MindTap Course List)

Mechanical Engineering

ISBN:

9781337093347

Author:

Barry J. Goodno, James M. Gere

Publisher:

Cengage Learning

Engineering Mechanics: Statics

Mechanical Engineering

ISBN:

9781118807330

Author:

James L. Meriam, L. G. Kraige, J. N. Bolton

Publisher:

WILEY

SEE MORE TEXTBOOKS