Download presentation
Presentation is loading. Please wait.
Published byHolly Simon Modified over 9 years ago
1
Tools ManufacturingProcesses
2
Outline Types of Tools Tool Geometry Cutting Fluids EffectsTypes Tool Wear FormsCauses Failure Modes Critical Parameters Horsepower Used Operating Temperature Feed and Speed Tool Life
3
Types of Tools
4
Tool Geometry Single Point Tools Multiple Point Tools Chip Breakers Effects of Material on Design
5
Single Point Tools
6
Multiple Point Tools
7
Chip Breakers
8
Important Tool Properties -High hardness -Resistance to abrasion, wear and chipping of the cutting edge -High toughness/impact strength -High hardness at high temperatures -Resistance to bulk deformation -Chemical stability (does not react or bond strongly with the work material -High modulus of elasticity (stiffness) -Consistent tool life -Proper geometry and surface finish
9
Tool Materials -Carbon and medium-alloy steels -High-speed steels -Cast-cobalt alloys -Carbides -Coated tools -Alumina-based ceramics -Cubic boron nitride -Silicon-nitride-base ceramics -Diamond -Whisker-reinforced materials
10
Cutting Speeds of Tool Materials
11
Cutting Fluids Effects -coolant -lubricant -flushes chips -reduces oxidation of heated surfaces Types -cutting oils -emulsified oils -chemical fluids
12
Cutting Fluid Application Flooding -≥ 3 gallons per minute per tool Misting -atomized fluids -a health hazard (OSHA limit =.2 mg/m 3 ) High Pressure Systems -often applied through the tool
13
Tool Wear Forms -crater wear -flank wear -chipping Causes -abrasion -adhesion -diffusion -plastic deformation
14
Crater Wear and Flank Wear Crater wear Flank wear
15
Failure Modes Fracture Temperature Failure Gradual Wear
16
Critical Parameters Horsepower Used Operating Temperature
17
Horsepower Used MaterialBrinellHardness Unit Horsepower hp u hp/(in 3 /min) CarbonSteels 150-2000.6 201-2500.8 251-3001.0 CastIrons 125-1750.4 175-2500.6 Aluminum50-1000.25 Values of Unit Horsepower for Various Work Materials
18
Operating Temperature
19
Feed and Speed Speed – the rate at which the tool point moves as it rotates (in a lathe, the rate at which the cutting point on the workpiece rotates) Feed – the rate at which the tool is fed into/along the workpiece
20
Feed and Speed V = πDN/12 V = surface cutting speed (ft/min) D = diameter of rotating object (in.) N = rotation rate (RPM)
21
Feed and speed Example: Assume a high-speed steel saw with 100 teeth and a diameter of 6 inches is used to cut aluminum. Determine the proper RPM and feed rate. V (HSS, aluminum) = 550-1000 ft/min [in table] N = 12V/(πD) = 12(550-1000)/(π6) = 350-637 RPM Feed (aluminum, saw) =.006-.01 in/tooth [in table] (.006-.01)100 teeth =.6-1in (.6-1)350 RPM = 210-350 in/min Start with the lowest values. They can be increased so long as the finish is acceptable.
22
Tool Life F. W. Taylor, 1907 Taylor Tool Life Equation vT n = C vT n = C(T n ) ref
23
Cutting Performance How do we know if cutting parameters are optimal? 1.Surface finish 2.Tool wear 3.Chip shape 4.Sound 5.Cutting time 6.Heat
24
Summary Tools fail slowly with gradual wear or suddenly with fracture Cutting fluids help reduce the effects of wear and temperature failure The materials of the tool and the workpiece affect the tool shape and life Higher cutting speeds increase the operating temperature and decrease tool life It is necessary to calculate proper feed and speed to prevent excessive tool wear
25
██████ The End
Similar presentations
© 2025 SlidePlayer.com. Inc.
All rights reserved.