Machining
29
Machining INT 201 INT 201 Eastern Kentucky Eastern Kentucky University University Metal Cutting Process Lecture References: 1) Degarmo E.P., Black J.T., Kosher R. (2003). Materials and Processes in Manufacturing, 9 th edition. Wiley 2) Repp, V. (1994). Metalwork: Technology and Practice, 9 th edition. McGraw-Hill 3) Groover, M. (2004). Fundamentals of Modern Manufacturing: Materials, Processes, and Systems, 2 nd edition. Wiley 4) Chen, C.S. (2001) ITEC 502: Advanced Design and Manufacturing [Course]. Iowa State University
description
Machining. Metal Cutting Process. INT 201 Eastern Kentucky University. Lecture References: Degarmo E.P., Black J.T., Kosher R. (2003). Materials and Processes in Manufacturing, 9 th edition. Wiley Repp, V. (1994). Metalwork: Technology and Practice, 9 th edition. McGraw-Hill - PowerPoint PPT Presentation
Transcript of Machining
Machining
INT 201INT 201
Eastern Kentucky UniversityEastern Kentucky University
Metal Cutting Process
Lecture References:
1) Degarmo E.P., Black J.T., Kosher R. (2003). Materials and Processes in Manufacturing, 9 th edition. Wiley
2) Repp, V. (1994). Metalwork: Technology and Practice, 9 th edition. McGraw-Hill
3) Groover, M. (2004). Fundamentals of Modern Manufacturing: Materials, Processes, and Systems, 2nd edition. Wiley
4) Chen, C.S. (2001) ITEC 502: Advanced Design and Manufacturing [Course]. Iowa State University
Lesson Objectives
1. REVIEW: Fundamentals of Machining
2. Identify the basic parameters associated with machining (milling)
3. Understand how these basic parameters are used to create and remove chips
4. Understand that machine parameters are directly related to type of material and the machine
Machining Fundamentals
REVIEW
•Machining is a process of removing unwanted material from a workpiece in the form of chips.
•Making and removing chips
•Importance of lubricants
•$60 billion spent annually on metal removal operations
Machining Fundamentals
Basic machine processes
• Milling Machines
Machining Fundamentals
SPINDLE
KNEE
BASE
TABLE
COLUMN
VERTICALLYVERTICALLY
LONGITUDINALLYLONGITUDINALLYTRANSVERSELYTRANSVERSELY
Basic Machining Parameters
Basic Machining Parameters
• Cutting Speed
• Spindle Speed (RPM)
• Feed Rate
• Metal Removal Rate
• Chip Load
• Machine Horse Power
Machining variables such as cutting speed, RPM, table feed rates, metal removal rates, and depth of cut all depend on:
• Work material
• Tool material
• Specific process/equipment
Basic Machining Parameters
Cutting Speed (SFPM)
• Cutting speed is the distance a point on the circumference of the milling cutter travels in one minute
• Measured in Surface Feet per Minute (SFPM)Surface Feet per Minute (SFPM)• Calculated at the outside diameter of the cutter
• Different cutting speeds should be used when machining different metals– With cutting speeds too fast, cutter will
overheat and dulls rapidly– With cutting speeds too slow, time is wasted
and production costs will increase
Cutting Speed (SFPM)
Cutting Speed (SFPM)
• Factors affecting cutting speeds in milling:– Material properties, cutting tool (HSS, carbide, cast alloy), cutting
fluids
• Cutting speed recommendations for various materials and tooling combinations can be found in sources including: Tooling Mfg. & Engineering Handbooks (Machinist Handbook, etc)
SuggestedCutting Speed Range
Material SFPM
Low-Carbon Steel 80-100Stainless Steel 60-80Aluminum (and its alloys) 400-1000Brass 200-300
Cutting Speed Formula
SFPM = (π * D * N)/12where
SFPM = Surface Feet Per Minuteπ = Circumference constant per inch of DiameterD = Diameter of the cutter, measured in inchesN = revolutions per minute of the spindle (RPM)12 = 12 inches per foot (conversion calculation to
feet)
Cutting Speed Example
If a 2 inch dia., 6 tooth milling cutter is turning at 100 revolutions per minute (RPM), what is the calculated cutting speed of the cutter (SFPM)?
ft/min surface 52.33 (628)/12 SFPM
in/ft 12RPM))/ (100 inches) (2 ((3.14) SFPM
N)/12 D ( SFPM
Spindle Speed (RPM)
The speed of the milling machine is
measured at the spindle and is measured
in REVOLUTIONS PER MINUTE (RPM)
Finding N (RPM)
D *
12 * SFPM
N
Same equation; different arrangement
SFPM = (π * D * N)/12
Determining RPM
• When milling with a 3” diameter, 8 tooth milling cutter with a recommended cutting speed of 250 SFPM tooling material combination, what is the recommended RPM?
RPM 320 5.1839.42
3,000
in 3*3.14
12*SFPM 250
D * π
12 * SFPMN
Feed Rate
• The linear distance moved along any machine axis, by the cutting tool in inches per minute.
• Feed rate in milling is determined by multiplying:– Number of teeth on the cutter– Chip load per tooth– Speed of the cutter (N)
Chip Load
Chip Load or Feed per Tooth
– The Chip Load is the amount of material removed by each tooth of the milling cutter during one revolution
–Chip load recommendations for various materials and tooling combinations can be found in machining and engineering handbooks
Milling Feed Rate Formula
F = N * Ct * Twhere
F = Feed rate in inches per minute
N = Spindle RPM
Ct = Chip Load per tooth [feed per tooth]
T = Number of teeth on cutter
Calculating Feed Rate
A 6 inch dia., 12 tooth milling cutter is turning at 250 RPM. The recommended chip per tooth is 0.004”. What is the feed rate?
F = N * Ct * T = 250 RPM * 0.004”/tooth * 12 teeth
F = 12” per minute
Metal Removal Rate
Metal Removal Rate (MRR) is the volume of material removed from the work piece in one minute.
Limited to available machine power
How much material is removed in 1 minute
MRR Formula
MRR = W * D * Fwhere
MRR = Cubic inches removed per minute
W = Width of Cut
D = Depth of Cut
F = Feed rate
MRR Graphic
Depth
Width
Feed Rate
Volume =
In3 / min
MRR Example
What is the MRR of a surface 3 inches wide that is to be milled with a 6 tooth milling cutter. Each depth of cut is 0.125 inches and the table feed rate is 4 inches per minute
3”
.125”
Feed Rate = 4”/min
MRR Example
3”
.125”
Feed Rate = 4”/min
MRR = W*D*F
MRR = (3”) * (0.125”) * (4” per minute)
MRR = 1.5 cubic inches per minute (in3/min) of material removed
Horse Power (specific) HPs
• HPs = Horse power required to remove 1 cubic inch (in3/min) of material per minute
• All machined materials have a HPs rating• HPs is used to determine the HP required for
machining.• The standard HPs = 1
– Materials with HPs > 1 require more than 1 HP/minute to remove 1 in3 of material
– Materials with HPs < 1 require less than 1 HP/minute to remove 1 in3 of material
• HPs can be found in machining and engineering handbooks
Horse Power Formula
HP = HPs * MRRwhere
HP = Horse Power required to make a desired cut
HPs = specific Horse Power of material
MRR = Material Removal Rate
HP Example
How much Horse Power is required to machine a part with a desired MRR of 3.94 in3/min and a specific Horse Power (HPs) of 1.8?
HP = HPs * MRR
HP = 1.8 * 3.94
HP = 7.1
Review
What is the maximum MRR of a material with a 1.6 HPs on a 1.2 HP machine?
How much material can be removed from the same material on a 7.1 HP machine?
Review
Machining variables such as cutting speed, RPM, table feed rates, metal removal rates, and depth of cut all depend on:
• Work material
• Tool material
• Specific process/equipment
WHY?WHY?
