Engineering, 18.02.2020 01:53 k3ydag0at
In orthogonal machining, the tool has a rake angle α = 10°, chip thickness before cut is 0.5 mm, chip thickness after cut is 1.15 mm and depth of cut is 3 mm. The cutting and thrust forces are measured at Fc = 1550 N and Ft = 1270 N, while the cutting speed is 60 m/min. Determine:
a. machining shear strain.
b. shear stress
c. cutting power
d. coefficient of friction between tool and chip (µ)
e. shear angle
f. shear force, Fs
g. chip velocity
h. shear velocity
i. MRR
j. specific energy
k. friction power
l. shear power
m. Gross power to operate the machine tool P, if the mechanical efficiency is 0.87.
n. draw the merchant’s circle by using a reasonable scale
p. resultant force, R
q. friction angle, ß
Answers: 3
Another question on Engineering
Engineering, 03.07.2019 14:10
Explain the difference laminar and turbulent flow. explain it with the shear stress and the velocity profiles.
Answers: 1
Engineering, 03.07.2019 14:10
When at a point two solid phase changes to one solid phase on cooling then it is known as a) eutectoid point b) eutectic point c) peritectic point d) peritectoid point
Answers: 3
Engineering, 03.07.2019 14:10
Amass of 1.5 kg of air at 120 kpa and 24°c is contained in a gas-tight, frictionless piston-cylinder device. the air is now compressed to a final pressure of 720 kpa. during the process, heat is transferred from the air such that the temperature inside the cylinder remains constant. calculate the boundary work input during this process.
Answers: 2
Engineering, 04.07.2019 18:10
The mass flow rate of the fluid remains constant in all steady flow process. a)- true b)- false
Answers: 1
You know the right answer?
In orthogonal machining, the tool has a rake angle α = 10°, chip thickness before cut is 0.5 mm, chi...
Questions
Chemistry, 19.03.2020 08:36
Mathematics, 19.03.2020 08:36
History, 19.03.2020 08:36
Physics, 19.03.2020 08:37
