Forming Rotary Dresser
An Application Example of Forming Rotary Dresser
RZ type
SZ type
SX type
Types
Abrasive Surface
Linear Guide
Tap
Turbine Blades (Aerospace, Power Generation)
Abrasive Grain Array
Random
Regular
Regular
Our high concentrate and random setting technology achieves long tool life and high accuracy. Our unique precision electroforming and precision machining technologies enables us t o achieve any kind of complicated pro le. Also, we offer wider variety of option.
With our precise diamond setting technology, concentration can be controlled as per your request. Higher electroforming technology as same as RZ type can achieve high precision grinding with maintaining good sharpness. This is also suitable for large-sized plunge dressing.
precision powder metallurgy technology and high-precision diamond lapping technology works greatly for dressing that requires sharpness. It is effective even for traverse dressing.
Features
Ball Screws
Wheel Hub Units (Automotive)
Engine Parts (Automotive)
Production Processes
Electro-Deposition
Electro-Deposition
Sintering
Outer Diameter (mm)
φ 50–200
φ 50–200
φ 20–180
Width (mm)
≤ 200
≤ 200
≤ 200
Various Bearings
Various Steering Parts
Hydraulic Parts
Grit Size
#20–#140
#16–#20
#16–#20
Prof ile
Complex / Fine
Form
Form
Series
Optimized Sharpness, Accuracy, and Wear Resistance
★★★
★★☆
★★☆
Profile Accuracy
Conventional forming rotary can be applied our Optimard spec, which specializes in sharpness, accuracy and wear resistance.
Specialize in Sharpness
★★★
★★☆
★★☆
Surface Roughness
Specialize in Accuracy
★★☆
★★★
★★☆
Sharpness
Specialized for High Wear Resistance
Recommended Dressing Conditions (Plunge Dress)
Conventional Dresser (RZ,SZ, SX)
High
Conventional Grinding Wheel
Hard Conventional Grinding Wheel
CBN Wheel
Wear Resistance
Dress Direction
Down
Down
Down
Spitz
Luxa
Stark
Types
Peripheral Speed Ratio
0.25–0.5
0.3–0.9
0.3–0.9
Dress Amount (mm)
0.02–0.03
0.02–0.03
0.01 – 0.015
Feed Rate (µm/revolution)
0.5–1
0.1–0.5
0.01–0.5
Abrasive Surface
Dress Out (sec.)
0–3
0–3
0–3
Features
Focus on Sharpness
Focus on Accuracy
Focus on Wear Resistance
Peripheral Speed Ratio
The Spec optimized for sharpness by regular array or lower concentration treatment. Especially it works greatly for reducing dressing load, chatter and burning issue in wider grinding wheel.
High-precision specialized spec that achieves high pro le accuracy as well as ne sharpness. Excellent shape stability supports quality control of workpieces.
The spec which designed for maintaining sharpness as well as improving wear resistance. It performs high pro le accuracy even in high-load dressing with CBN wheels and hard grinding wheels.
Vr (Speed)=R.P.M x O.D x π Vs (Grinding wheel peripheral speed) =Grinding wheel revolution (min -1 ) ×O.D.×π * In case of up dress, please add "-", minus, to the number after the calculation.
Vr Vs
Peripheral Speed Ratio =
Features
Dressing Method
φ 50–200
φ 50–200
φ 50–200
Outer Diameter (mm)
Down Dressing
Width (mm)
10–100
10–100
10–100
Grit Size
#16–#40
#30–#80
#30–#80
Process Image
Applicable
RZ, SZ, SX
RZ
RZ
Life (Number of Dresses: Index)
Dress Resistance (Index)
Accuracy Maintenance
0 0.5 1 1.5 2 2.5 3 3.5
Conventional Dresser
Profile Accuracy Improvement
Dressing Method
Plunge
Angular
Angular
Up Dressing
Comparison with Conventional Products
Standard Value
20% Less
Grinding Method
Plunge
Plunge
Angular
3 Times
Conventional Dresser
This is standard dressing method that uses same profile as a parts to be ground.
Profile grinding at end face without burn mark is available. High dressing ability spec such as Optimard Spits is highly recommended.
Conventional Dresser
Features
0
100
200
300
0 20 40 60 80 100 120
Number of Dress
1
2
Traverse Rotary dresser
Example of Rotary Dresser for Profile Forming
AR1
AR2
AR3
AR4
AR5
AR6
AR7
Prof ile
Used for traverse dressing of grinding wheels.
Used for total forming shape of grinding wheel.
Uses prismatic diamonds that offers consistent sharpness and wear resistance.
Diamonds set on both shoulders are
This is a double- shouldered radius type using natural diamonds. This type is used for forming wide grinding wheels and for forming a radius around the
This is a Impregnated type with ne diamond grains bonded by sintered metal. It has a long life, but the wider the abrasive grain layer, the worse the cutting ability.
Cup-shaped dresser suitable for dressing small-diameter grinding wheels.
Various Gears
Tap
Ball Screws
Various Shafts
Needle Valve
suitable for processing micro-pro le.
Excellent for micro-shape machining.
Features
Allesta
Traverse Rotary Dresser for High Precision Profile
periphery of the grinding wheel.
Various customizations are available with our micro-shape machining technology at the tool edge to meet a wide range of requests.
Features • Rotary dresser for traverse forming that enables machining of fine shapes by its acute edge angle design. • The abrasive grain and grain arrangement that specialized for traverse process enables to achieve high accuracy and long life. Applications • Interpolate dressing of conventional grinding wheel and CBN wheel for profile grinding. • Bearings, Ball screws, Needle valves, Various shafts, Gears, Taps, Rolling dies
Edge R (mm)
-
≥ 1.5
≥ 0.25
≥ 0.25
≥ 0.25
-
-
Profile Accuracy (µm)
≥ 1.5
≥ 2
≥ 2
≥ 2
≥ 2
-
-
Edge Angle (degree)
-
-
≥ 40
-
-
-
-
Outer Diameter (mm)
≤180
≤ 180
≤ 180
≤ 180
≤ 180
≤ 200
≤ 200
★★★
★★☆
★★★
★★☆
★★☆
★★☆
★★☆
Wear Resistance
Wear Resistance Evaluation Result
★★☆
★★☆
★★★
★★☆
★☆☆
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Sharpness
Applicable Range Abrasive Grain Size
0.05
0.3–0.6 mm (Square Column)
0.04
Types
SX
SX
SX, CWN
SX
SX
X
SX, X, CWN
5 times better Wear resistance!
0.03
φ 50–200 mm
Outer Diameter
SX type: Rotary dresser with diamonds fixed by hard metal bond X type: Impregnated type rotary dresser CWN (crown) type: Rotary dresser with prismatic diamonds fixed by Ni plating
0.02
≥ 18°
Edge Angle
≥ 18°
R≥ 0.1
Criteria for Dresser Life
0.01
Edge R
≥ 0.1 mm
Radial Profile Accuracy
0
Recommended Dressing Conditions (Traverse Dress)
≤ 1.5 µm
5 3.5
20 21
0
10
15
25
30
Amount of Grinding Wheel Wear (cm 3 )
Conventional Grinding Wheel
Hard Conventional Grinding Wheel
CBN Wheel
Dress Direction
Down
Down
Down
Disc Dresser
Rotary Dressers for Gear Grinding Process
Peripheral Speed Ratio
0.25–0.5
0.3–0.9
0.3–0.9
As a dresser for shaping worm-shaped grinding wheels used in gear grinding, it realizes "higher precision gears" and "reduced grinding costs" by extending dresser life.
Dress Amount (mm)
0.02
0.02
0.01
Infeed Rate (µm/pass)
5–30
3–5
2–3
Features • Based on information such as Workpiece gear specifications, grinding wheel shape and specifications, we design a dresser that achieves the required tooth surface quality. • Extremely high tooth profile accuracy of 0.001 mm or less can be obtained. • High ability to maintain tooth profile accuracy shape and low dresser life variation contribute to reduced grinding costs. Applications • Dressing of worm-shaped grinding wheels used for generating the tooth form of automotive and machine gears
Dress Out (Traverse Cycles)
0–4
0–4
0–4
Feed Rate Feed Rate (mm/min) = C × Rotary Dresser Width × Grinding Wheel Revolution (min -1 )
Dressing Method
Grinding Method
C
Disc Dresser Contour Shape
Standard
0.025–0.1
Process Image
1mm
Efficient Grinding High Speed Grinding
0.125–0.2
Centerless Grinding
0.005 – 0.01
Dressing Method
Interpolating
Traverse
Cup Type
Dresser Shape Data ( R1000 )・・ 1μm
3
4
Technical Data
Technical Data In dressing, the surface roughness of grinding wheels is influenced by elements such as: 1. Peripheral speed ratio (Vr/Vs), 2. Infeed per revolution of wheel (Ar), and 3. Dress out (Na).
Design Information for Forming Rotary Dresser
Tolerances of Rotary Dresser Designs (mm)
Dimensional Tolerances of Rotary Dressers Set approx half of the allowable tolerance of the workpiece.
M
W
U
1. Peripheral Speed Ratio ① Influence of Peripheral Speed Ratio on Grinding Wheel Surface Roughness • Control of the grinding surface accuracy by up-dressing is easier than by down-dressing • Higher feed rate creates more open grinding surface (grinding ability increases)
Rotary Dresser Accuracy Limits
Other tolerances available upon request
15
Test Condition
Item Factor
Symbol Accuracy (mm)
Illustration
WA60K #20/30 Vs=29m/s Na=0
Grinding Wheel Rotary Dresser Grinding Wheel Peripheral Speed Dress Out Infeed Per Rev.of Grinding wheel Ar = 0.18μm/rev
L L
Width
L
± 0.005
S
10
U value
W value RZ type ≥ 0.5Z SZ type ≥ 0.5Z SX type ≥ 4Z
Y value M value
Radius
R
± 0.002
RZ type ≥ 10 SZ type ≥ 10 SX type ≥ 3
RZ type ≥ 10
≥ L
Down Dressing
Up Dressing
0.002
SZ type
≥ 10
≥ L
Step
S
± 0.001
R
R
R
5
SX type
≥ 4
≥ 0.5L
= 0.36μm/rev = 0.54μm/rev = 0.72μm/rev
Down Dress
Up Dress
Profile Accuracy
0.002
Prof ile
0 1.5 1.0 0.5 0 -0.5 -1.0 -1.5
P P P
Concave R Convex R Convex R
Peripheral Speed Ratio (Vr/Vs)
0.002
θ
Concave R
Angle
± 1´
② Influence of Peripheral Speed Ratio on Dressing Force • Larger peripheral speed ratio allows higher normal force (increasing in grinding ability • Tangential force shows the same tendency as normal force, but the value is much smaller
8
0.6
ー
Straightness
0.002
nP
0.5
6
P P P
Pitch Accumulative Pitch
P nP
± 0.002 ± 0.004 + 0.005 − 0
0.4
4
P value
*Convex R value *Concave R value
0.3
RZ type
≥ 0.1
≥ 0.03
RZ type
≥ 0.3
φ H
Bore
2
0.2
0.002
SZ type
≥ 0.2
≥ 0.15
Parallel
0.002
0.1
0
0.002
A
SX type ≥ 0.15 *Value depending on diamond grain sizes ≥ 0.2
Pro le
1.0
0.5
0
-0.5
-1.0
1.0
0.5
0
0.005 A
Control
Peripheral Speed Ratio (Vr/Vs)
Body
Peripheral Speed Ratio (Vr/Vs)
Perpendicularity
0.002
0.002
Pro le
2. Infeed Rate ① Influence of Infeed Rate of Grinding Wheel Surface Roughness • Higher feed rates create a more open grinding surface (grinding ability increases) • Longer dress-out time diminishes sharpness of the grinding surface
Runout of Profile
0.005
② Influence of Infeed Rate on Dressing Force • Larger feed rate increases normal force. (Grinding ability increases) • Tangential force shows the same tendency as normal force, but the value is much smaller.
A
H
Runout of Control
0.002
(Na=Dress out wheel rotation frequency)
Troubleshooting
6
0.5
Vs Vr Down Dress =0.81
Down Dress Na=0
10
0.4
Corrective Action
8
4
Trouble Details
Cause
0.3
Vs Vr Down Dress =0.16
Grinding wheel, dresser, and facility speci cation changes
Maintenance, change of dress conditions
6
Up Dress Na=0 Down Dress Na=80
0.2
2
Large dressing noise Chatter occurs
Vibrations
Cause of abnormal vibration isn't eliminated
• Check the run-out of the dresser • Check the unbalance between grinding wheel and dresser • Increasing the peripheral speed relative to the grinding wheel Down-dress: Reduce dresser rpm Up-dress: Increase dresser rpm
Vs Vr Up Dress =0.81
4
0.1
Up Dress Na=80
• Reduce diamond concentration of dresser • Increase machine rigidity • Increase the driving force of the dressing device
High dressing Load
0
2
0.1 0.2 0.3 0.4 0.5 0.6
0
0.18
0.36
0.54
0
0.18 0.36 0.54 0.72
Infeed Rate (μm/rev)
Infeed Rate (μm/rev)
Infeed Rate (μm/rev)
• Reduce infeed rate • Increase feed rate • Shorten dress-out
3. Dress Out Influences of Dress Out on Grinding Wheel surface Roughness • Longer dress out time increases roundness of the grinding surface, but reduces sharpness.
Burn mark
Temperature rise of workpiece Grinding wheel is dull
• Use softer grinding wheel • Use larger Grit grinding wheel
10
• Increase total dressing amount
• Reduce diamond concentration of dresser
• Avoid end-face grinding with angular grinding
8
Coolant is not supplied suf ciently
• Increase coolant amount
• Increase the amount of diamond protrusion of the dresser
6
• Adjust coolant nozzle position • Avoid end-face grinding with angular grinding
Down Dress Up Dress
4
Grain shedding due to early bond retreat
Insuf cient evacuation of grinding debris
• Increase coolant amount • Adjust coolant nozzle position • Increase coolant amount • Reduce infeed rate • Shorten dress-out • Check the run-out of the dresser
Abnormal wear
2
Diamond wear
Dresser temperature rise
0
80 150 240 320 Grinding Wheel Rotation Speed During Dress-Out (Na)
Dresser vibrations
• Increase machine rigidity
• Check the unbalance between grinding wheel and dresser
Precautions for Use of Rotary Dressers
Unsuitable Dresser selection
• Increase diamond concentration of dresser • Reduce the size of the abrasive grains
1. Do not directly touch the diamond part of the rotary dresser, which has a small edge angle and edge radius. Use cut-resistant gloves and handle with care. 2. When mounting and removing a rotary dresser on and from the spindle, do not strike it with a hammer. 3. When a rotary dresser is mounted on the spindle, be sure that the runout of the reference surface is less than 2µm in both the radial and axial directions. If the runout is large, turn the rotary dresser by a half turn and set it again. 4. Prior to starting dressing, run the grinding wheel and rotary dresser under no load to check for abnormal noise and vibration. 5. During dressing, keep supplying an ample amount of grinding fluid. This will improve the dressing performance and prolong the life. Make sure the nozzle is located properly and the nozzle is not clogged. Never use the rotary dresser without coolant. 6. When bringing the rotary dresser in contact with the grinding wheel for dressing, exercise special care. Do not hit the rotary dresser against the grinding wheel with a shock. Be sure that the infeed rate will not exceed the setting. The rotary dressers are precision equipment. When using them, be sure to observe the following precautions.
Poor surface roughness
Unsuitable grinding wheel spec Grinding wheel grain size is too large
Workpiece contamination
Clogging of grinding debris
• Increase coolant amount • Adjust coolant nozzle position
Dirty or contaminated coolant
• Clean the coolant path • Replace coolant
Vibrations
Cause of abnormal vibration isn't eliminated
• Check the unbalance between grinding wheel and dresser • Increase machine rigidity • Check the run-out of the dresser
Poor grinding wheel roundness Insuf cient grinding wheel forming • Check the run-out of the dresser
• Increasing the peripheral speed relative to the grinding wheel Down-dress: Reduce dresser rpm Up-dress: Increase dresser rpm • Reduce infeed rate • Apply longer dress-out
For safe use of the rotary dresser, read and understand Rotary Dresser Instruction Manual thoroughly.
5
6
Technical & Reliable Network for A.L.M.T. Corp. ■ Head Office
Sumitomo Fudosan Shiodome Hamarikyu Building, 8-21-1, Ginza, Chuo-ku, Tokyo, 104-0061 Japan Phone +81-3-6733-3617 Fax +81-3-6733-3621
Domestic Production Network (Diamond / CBN Tools) ■ Harima Works (Grinding Wheel, Cutting Tool, Rotary Dresser) 1816-174, Kotaka, Kato-city, Hyogo 679-0221 Japan Phone +81-795-48-5067 Fax +81-795-48-5071 ■ Awaji Plant (Diamond Drawing Dies, Wear-Resistance Products) 628, Yura, Yura-cho, Sumoto-city, Hyogo 656-2543 Japan Phone +81-799-27-0317 Fax +81-799-27-2485
Harima Works
Domestic Sales Network ■ Tohoku Office
■ Hamamatsu Office
■ Osaka Office
■ Kita-kanto Office
■ Hiroshima Office
■ Tokyo Office
■ Kyushu Office
■ Mikawa-anjo Office
Global Network (Diamond / CBN Tools) <North America> ■ Sumitomo Electric Carbide, Inc. (Chicago) ……(Sales of Diamond Tools) 1001. Business Center Drive, Mt. Prospect, IL 60056-2181, U.S.A. Phone +1-847-635-0044 Fax +1-847-635-9335 ■ Sumitomo Electric Carbide, Inc. (Detroit) …… (Sales of Diamond Tools) 26800 Meadowbrook Road,Suite 120 Novi, MI 48377, U.S.A. Phone +1-734-451-0200 Fax +1-734-451-5338
<Central America> ■ Sumitomo Electric Hardmetal de Mexico. S.A. de C.V. (Mexico)
…… (Sales of Diamond Tools)
Avenida Eugenio Garza Sada No. 42 Pocitos Aguascalientes, Ags., 20328, Mexico Phone +52-449-993-2740 〜 41
<Asia> ■ A.L.M.T. Diamond Dies (SUZHOU) Co., Ltd. (Suzhou, China)
■ A.L.M.T. Asia Pacific Pte. Ltd. (Singapore)
…… (Sales of Diamond Tools and Diamond Drawing Dies)
…… (Manufacture and Sales of Diamond Drawing Dies) Unit 24E, 25D, 25E of Suchun Industrial Square, #428 Xinglong Street
No.2 Boon Leat Terrace #03-02 Harbourside 2 Singapore 119844 Phone +65-6271-9252 Fax +65-6274-2915 ■ A.L.M.T. Asia Pacific Pte. Ltd. (Malaysia)
Suzhou Industrial Park, Jiangsu, P.R. 215024, China Phone +86-512-62836195 Fax +86-512-62836176 ■ Sumitomo Electric Hardmetal Trading (Shanghai) Co., Ltd.
…… (Sales of Diamond Tools and Diamond Drawing Dies)
8F-1A,Tower 4 @PFCC Jalan Puteri 1/2, Bandar Putei 47100, Puchong,Selangor Malaysia Phone +60-3-8069-1090 ~ 91 Fax +60-3-8069-1094 ■ A.L.M.T. (Thailand) Co., Ltd. (Bangkok, Thailand)
…… (Sales of Diamond Tools) Room J, 6/F Huamin Empire Plaza, No.728 Yan An Road(W), Shanghai, 200050, China Phone +86-21-6212-9271 Fax +86-21-6212-9272 ■ Sumitomo Electric Hardmetal Trading (Shanghai) Co., Ltd. (Guangzou) …… (Sales of Diamond Tools) Room 21, A22F, China Shine Plaza, No.3-15 Lin He Xi Road, Tian He District, Guangzhou, 510610, China
…… (Sales of Diamond Tools and Diamond Drawing Dies) 54 B.B Building 15th Floor Room 1511 Sukhumvit 21 (Asoke), North
Klongtoey Wattana, Bangkok 10110 Thailand Phone +66-2-2612231 ~ 2 Fax +66-2-2612230 ■ A.L.M.T. (Thailand) Co., Ltd. (Wellgrow, Thailand)
Phone +86-20-3881-5582 Fax +86-20-3891-0904 ■ Sumitomo Electric Hardmetal Taiwan Co., Ltd.
…… (Manufacture of Diamond Tools)
90/2 Moo 9 Wellgrow Industrial Estate Bangna-trad Road., T.Bangwua A.Bangpakong Chachoengsao 24180 Thailand
…… (Sales of Diamond Tools) 13F, No.156, Section 1, Zhongshan Rd., Banqiao District, New Taipei City, 22065, Taiwan Phone +886-2-29596721 Fax +886-2-29596720
Phone +66-38-522291 ~ 5 Fax +66-38-522290 ■ A.L.M.T. (Thailand) Co., Ltd. (Korat, Thailand)
…… (Manufacture of Diamond Drawing Dies)
Mooban Bannaklang 567 Moo 1 T.Naklang A.Soongnuen Nakhonratchasima 30380 Thailand Phone +66-44-335190 Fax +66-44-335300
Sumitomo Fudosan Shiodome Hamarikyu Building, 8-21-1, Ginza, Chuo-ku, Tokyo, 104-0061 Japan Phone +81-3-6733-3617 Fax +81-3-6733-3621 https://www.allied-material.co.jp/en.html
* Specifications are subject to change without prior notice.
2024.09 (T) 500
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