Run Thermal Stress analysis of the following pump housing (housing.prt is given in E-learning) . The housing is made of Aluminium and mounted to a pump which is held at a constant temperature of 60 °C. The mating face on the pump is also held at this temperature. The interior surfaces of the pump are kept at a constant temperature of 90 °C by the fluid and the exterior surfaces are modelled using a simplified convection correlation for stagnant air at 20 °C. • The flat mating surface of the housing is prevented from moving or deforming in the normal direction. Another frictionless supports will be applied to the 8 countersink portion of the mounting holes.

Run Thermal Stress analysis of the following pump housing (housing.prt is given in E-learning) . The housing is made of Aluminium and mounted to a pump which is held at a constant temperature of 60 °C. The mating face on the pump is also held at this temperature. The interior surfaces of the pump are kept at a constant temperature of 90 °C by the fluid and the exterior surfaces are modelled using a simplified convection correlation for stagnant air at 20 °C. • The flat mating surface of the housing is prevented from moving or deforming in the normal direction. Another frictionless supports will be applied to the 8 countersink portion of the mounting holes.

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

Give an example of an interconnected system of two tanks so that: the system is homogeneous the system is nonhomogeneous the systems has constant coefficients the systems has at least one non-constant coefficient Solve one of the systems you gave (use a constant-coefficient, homogeneous system) Please don't copy and paste solutions from Chegg
Learning Goal: To calculate minor head losses and pressure drops for pipe fittings. Minor losses in pipe flow are the result of disruptions to the steady laminar or turblent flow in a pipe by entrances, bends, transitions, valves or other fittings. In general, calculating these losses analytically is too complex. However, all of these losses can be modeled using terms of the form h = KL where Kr, is called the loss coefficient and is determined experimentally. This coefficient relates the minor head loss to the velocity head for the flow. For expansions and contractions, the loss coefficient is calculated using nine the velocity for the smaller diameter pipe. The table below gives some representative values for various minor head losses. These are representative only, and a more complete table would account for different kinds of fittings and connections (like threaded or soldered). Fitting Well-rounded entrance ≥0.15 Flush entrance Re-entrant pipe Discharge pipe Sudden contraction (d₂…
Thermocouples are devices used to measure temperature of a given sample or the surroundingmedium. These devices feature a “bead”, which has a spherical shape, and produces voltage upon changein temperature. For an engineering application at a pharmaceutical company, thermocouple devices arebeing tested for their responsiveness, i.e. how fast it can detect temperature changes in the environment(surrounding air). The engineers at this company have specified design constraints for an idealthermocouple: it must detect temperature changes no later than 1.5 minute, and the reportedtemperature value must be reasonably correct: at most %3 difference between measured and actualtemperature values is allowed.Four thermocouples from different vendors are being tested. Relevant properties of these devices arelisted below: The experiment involves placing the thermocouple from air at 20 °C to air at 150 °C, and monitoring thetime it takes for the measured values to reach 150 °C, which is the…
Help me solve this using MATLAB
In a concentrated solar power plant, molten salt tank is used to store the thermal energy from the sun during the day. The tank wall thickness is 3cm containing molten salt at a temperature of 390 degree Celsius. There is atmospheric air outside the tank at a temperature of 30 degree Celsius. Suppose heat is lost as a result of heat transfer from the molten salt to the atmospheric air. What is the mode of heat transfer in this condition? conduction then convection convection then conduction convection then conduction then convection conduction then convection then conduction
Help solve this USING MATLAB
Please Derive the following equations for the Hartnell governor 1. Effort of a governor 2. Power of a governor (Please send the solution as fast as possible I have assignments that I need submit in 2 hours )
Learning Goal: To calculate the maximum allowable stresses in pressure vessels, compute the minimum allowable thickness of pressure vessels to meet certain constraints, and observe and compare properties of different pressure vessel shapes. Engineers are considering two possible vessel shapes for storing fuel. One shape is cylindrical and the other is spherical. Each vessel would be constructed out of the same material such that its hoop stresses and longitudinal stresses would be no greater than 140 MPa. The cylindrical pressure vessel has an inside diameter of dc = 635 mm and a thickness of t = 14 mm . The spherical pressure vessel has an inside diameter of de = 735 mm and a thickness of t = 8 mm. Part A - Maximum allowable pressure in the cylindrical pressure vessel Determine the maximum allowable pressure, pc,max, in the cylindrical pressure vessel. Express your answer in MPa to three significant figures. ► View Available Hint(s) Pc,max = Submit ΑΣΦ Ps,max = Request Answer Submit…
You are tasked to design a cooling system for an ice rink. A standard ice rink has surface area ofArink = 1580 m2 . In this design, a technologically advanced solid state thermoelectric generatingcooling plate is placed in between concrete slabs. The following diagram contains the dimensionalparameters of the design (a) In the space below, with your best effort to correspond to the above diagram, draw a thermalcircuit that establishes the relationship between the cooling plate’s heat rate, Q, and the system’stemperatures and thermal resistances. Label the appropriate dimensions, thermal conductivities,convection coefficient, and temperatures. Ignore effects from contact resistance. (b) Given that the temperature at the top surface of the ice must be T ice = -5°C, obtain the requiredheat rate Q that must be drawn by the cooling plate in units Kilowatts. Be careful of +/- sign.Answer: ____________________________ [kW] c) Using the thermal circuit you established in Part (a), obtain the…
ools Fundamental of bio.. x 57 (73 of 286) e cdlaims compliance with the PDF/A standard and has been opened read-only to 4.13 Exercise Problems Problem 43 The uniform, horizontal beam shown in Fig. 4.51 is hinged to the wall at point A and supported by ar a cable attached to the beam at point C. Point C also th represents the center of gravity of the beam. At the other end, the cable is attached to the wall so that it makes an angle 0=68° with the horizontal. If the length of the beam is / = 4 m and the weight of the beam is W = 400 N, calculate the tension T in the cable and components of the reaction force on the beam at point A. Answers: T = 431 N, RAr = 162 N(→), RAy = 0 A Fie Fig. 4.51 Problem 4.3 Pr be 4.4 Using two different cable-pulley arrangements Problem
Learning Goal: To calculate the maximum allowable stresses in pressure vessels, compute the minimum allowable thickness of pressure vessels to meet certain constraints, and observe and compare properties of different pressure vessel shapes. Engineers are considering two possible vessel shapes for storing fuel. One shape is cylindrical and the other is spherical. Each vessel would be constructed out of the same material such that its hoop stresses and longitudinal stresses would be no greater than 120 MPa. The cylindrical pressure vessel has an inside diameter of de = 800 mm and a thickness of te = 25.0 mm. The spherical pressure vessel has an inside diameter of ds = 650 mm and a thickness of t = 11.0 mm. ▼ Part A - Maximum allowable pressure in the cylindrical pressure vessel Determine the maximum allowable pressure, pc,max, in the cylindrical pressure vessel. Express your answer in N to three significant figures. ► View Available Hint(s) Pc,max = Submit ΟΙ ΑΣΦ ↑ vec Previous Answers…
A Classwork for MENG420 - Heat Ti X b My Tutoring | bartleby + classroom.google.com/u/1/w/MTQ3MTM5MDC2NTY3/t/all C E Apps M Gmail YouTube Translate Маps Given-Problems-MENG420-Chapter-7.pdf Mount L Open with ▼ Problem 7.56 Hot water at 50 °C is routed from one building in which it is generated to an adjoining building in which it is used for space heating. Transfer between the buildings occurs in a steel pipe ( k = 60 W / m² .K) of 100-mm outside diameter and 8-mm wall thickness. During the winter, representative environmental conditions involve air at T =-5 °C and V=3m/s in cross flow over the pipe. a) If the cost of producing the hot water is $0.10 per kW.h, what is the representative daily cost of heat loss from an uninsulated pipe to the air per meter of pipe length? The convection resistance associated with water flow in the pipe may be neglected. b) Determine the savings associated with application of a 10-mm-thick coating of urethane ( k = 0.026 W /m.K ) to the outer surface of…