Công nghệ chế tạo máy | Cutting Speeds and Feeds Formulas

Cutting Speeds and Feeds Formulas | YCK2020

Tốc độ cắt gọt (Cutting speess) và bước tiến (Feeds) là những thông số quan trọng của quá trình cắt gọt kim loại.

Những thông số này sẽ giúp ta chọn chế độ cắt gọt tối ưu trên các máy công cụ cắt gọt kim loại, kể cả các máy công cụ điều khiển số CNC..Nó rất quan trọng trong ngành gia công cơ khí chĩnh xác.

Đây là những công thức giúp ta có được lựa chọn tối ưu chế độc cắt gọt. 

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Mọi người cũng tìm kiếm: Cutting Speeds and Feeds Formulas, Cutting Data, CAD/CAM, Dao Phay Dinh Hinh, Drill Cycles Speed Data, công nghệ chế tạo máy, Cutting Feeds, chế tạo máy, Hướng dẫn vẽ 3D,

The tool moves through the material at a specified rotational speed, defined in revolutions per minute (RPM), and feed rate, defined in inches per minute (IPM). Probably the most vexing problem for the beginning CNC machinist is selecting proper cutting speeds and feeds. This selection is actually more difficult on a CNC than a manual mill because, with a manual mill, the operator can feel the cutting pressure and alter the feed based in part on the cutting force.

CNC mills require calculating speeds and feeds in advance. These speeds and feeds can, and often are, adjusted at the machine based on chip shape and color, cutting sound, and machine horsepower meter readings.

The best source of data about cutting speeds and feeds for a specific tool, application, and material is the tool supplier. Much of this data is found on manufacturer's web sites or printed tooling catalogs. Tool sales representatives can be a valuable resource, so if you do a lot of machining, develop a good relationship with a knowledgeable representative.

Another source of speeds and feeds data is CAD/CAM software. These have become increasingly sophisticated and often provide good cutting data.

Yet even the best speed and feed data is just a starting point. Speeds and feeds require adjustment due to many factors including the maximum spindle speed or horsepower of the machine, rigidity of work holding, and the quality and condition of the machine tool itself.

The following pages provide cutting data for the most commonly machined materials and a methodology for calculating speeds and feeds. As always, use common sense. If the part is held by double sided tape, feeds based on vise work holding are probably too high. If the tool is very long and thin, speeds and feeds will likely require reduction.

Speed Formula

Milling machine cutting speeds are derived from the following formula:

Figure 3.14: Speed Formula

 

Speed is the rotational frequency of the tool (Spindle Speed) in revolutions per minute (RPM).

SFM (Surface Feet per Minute) is the speed at which the material moves past the cutting edge (outside diameter) of the tool in feet per minute. SFM values depend on the tool type, tool material, and material being machined.

Circumference is the circumference of the cutting tool in feet.

How Speed Formula is Derived

Because cutting tools are defined by their diameter in inches, this formula is rewritten and simplified as follows:

 

 

Figure 3.15: Speed Formula (Simplified)

Dia is the tool diameter in inches.

3.82 is a constant derived from 12/pi which converts the tool circumference in feet to diameter in inches.

Feed Formula

Cutting feeds are in IPM and use the following formula:

Figure 3.16: Feed Formula

Feed is the linear feed of the tool through the material in inches per minute.

Speed is the result of the speed formula (Figure 3.15) in revolutions per minute.

CL is the chip load, or how much material each cutting edge of the tool removes per revolution. Chip load is sometimes referred to as feed per tooth (FPT) or inches per rev (IPR).

NumFlutes is the number of cutting flutes. (For a twist drill, this value is one.)

Tap Feed Formula

For tapping operations, feed rate is based on the number of threads per inch and feed rate:

Figure 3.17: Tap Feed Formula

Feed is the linear feed of the tool through the material in inches per minute.

Speed is the result of the speed formula (Figure 3.15) in revolutions per minute.

TPI is the threads per inch of the tap. For example the TPI of a 1/4-20 tap is 20.

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Công Nghệ Chế Tạo Máy | Cutting Data | Troubleshooting Speed/Feed Problems | Best Practice Machining Parameters

Cutting Data | YCK2020

Thông số cắt gọt rất quan trọng trong Gia công cơ khí chính xác.

Bản Thông số cắt gọt này giúp cho các bạn đang học về Công nghệ chế tạo máy thêm nguồn tham khảo.

Hi vọng giúp cho các sinh viên Chế tạo máy và những người hoạt động về Cơ khí chế tạo, bạn có thể tìm kiếm bài viết này với từ khóa: Machining Parameters,Cutting Data,Mill Cutting Speeds,Corner Radius Tool,Drill Cycles Speed Data,Cutting Feeds,chế tạo máy,Dao Phay Ngon,compabua,Cutting Data,chế tạo máy,

Tables on the following pages provide basic speed, feed and cutting data for some of the materials commonly used for prototypes. Use the tool manufacturer's data instead whenever it is available.

Mill Cutting Speeds (SFM) surface ft/min

Table 3.5: Milling Speed Data (SFM)
Mill Cutting Speeds (SFM) surface ft/min
Material	HSS	Carbide
Aluminum	600	800
Brass	175	175
Delrin	400	800
Polycarbonate	300	500
Stainless Steel (303)	80	300
Steel (4140)	70	350

 

Table 3.6: Drill Cycles Speed Data (SFM)
Drill Cutting Speeds (SFM) surface ft/min
Material	Drilling	C-Sink	Reamer	Tap
Aluminum	300	200	150	100
Brass	120	90	66	100
Delrin	150	100	75	100
Polycarbonate	240	160	120	100
Stainless Steel (303)	50	35	25	35
Steel (4140)	90	60	45	35

 

Never use tools that have been used to machine metal to cut plastic. The sharp edge of the tool will be compromised and cutting performance and finish will suffer. A good practice is to keep two sets of tools: one for plastic and one for metal. High-speed steel cutters work best for plastics. Carbide cutters work better for aluminum and other metals.

 

Table 3.7: Feed Data (IPR)
Cutting Feeds (IPR) in/rev
Operation	Tool Diameter Range (in)
	<.125	.125-.25	.25-.5	.5-1.	>1.
Milling
Aluminum	.002	.002	.005	.006	.007
Brass	.001	.002	.002	.004	.005
Delrin	.002	.002	.005	.006	.007
Polycarbonate	.001	.003	.006	.008	.009
Stainless Steel (303)	.0005	.001	.002	.003	.004
Steel (4140)	.0005	.0005	.001	.002	.003
Drilling	.002	.004	.005	.010	.015
Reaming	.005	.007	.009	.012	.015

Best Practice Machining Parameters

Best practice machining parameters for prototype and short-production milling are different than for mass production. Production machining is obsessed with minimizing run time and maximizing tool life because even small improvements per part can result in significant cost savings.

Prototype and short run production seeks to maximize reliability. Obviously, it does not make sense to risk breaking a tool or scrapping a part trying to save a few seconds if only making a few parts.

Tables 3.8 and 3.9 on the following pages list recommended machining parameters for prototypes. The values are relatively conservative and work well for materials and tool types listed on the previous pages.

For materials or tools not listed, consult cutting data from the tool manufacturer.

Table 3.8: Machining Parameters
Recommended Machining Parameters
Operation	Parameter	Value
All	Clearance Height	1.0 inch
All	Feed Height	.1 inches
All	Rapid Height	As needed to clear clamps and fixtures
Mill (Roughing)	Stepover (XY)	50-80% of tool dia.
Mill (Roughing)	Stepdown (Z)	25-50% of tool dia.
Drill	Peck Increment	.05 inches
Spot Drill	Dwell	.5 seconds

 

Table 3.9: Stock Allowances
Stock Finish Allowances (inches)
Operation	Tool Diameter Range (in)
	<.125	.125-.25	.25-.5	.5-1.	>1.
Milling (XY)	.001	.005	.015	.020	.020
Milling (Z)	.001	.002	.005	.005	.005
Reaming	.005	.010	.012	.020	.030

 

Troubleshooting Speed/Feed Problems

Do not make the mistake of thinking that the only option when encountering a machining problem is to reduce feed rate. Sometimes that is the worst thing to do and decreasing speed and increasing feed may be a better option.

Be methodical. When a problem occurs, stop. Analyze what is happening, draw on all available resources, and then devise a solution to correct the problem. The Machinery's Handbook (Industrial Press Inc, 2008, New York, NY, ISBN: 978-8311-2800-5) contains extensive information about diagnosing and correcting cutting tool problems. This book is an essential reference for anyone using machine tools.

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