1804349 mahr scope broschuere control 2018 en++
TRANSCRIPT
Gear Measurement
MarShaft SCOPE 600 plus 3D A new dimension in gear measuring
Faster measurements with more process-reliablity
Complete acquisition of all features
Automated mesaurement directly in production
This is what we mean by EXACTLY.
MarShaft
NEW
Gear MeasurementMarShaft SCOPE 600 plus 3D
Starting point above the tooth.
Automatic detection of the tooth gap.
MarShaft SCOPE 600 plus 3D 2
Gear measurement in productionAutomated, fast and process-reliable
High-precision matrix camera and 2D probe system
The optical/tactile shaft measuring machine MarShaft
SCOPE 600 plus 3D has a high-precision matrix came-
ra, a new 2D touch probe and a motorized tailstock. A
special calibration of the linear axes (Z-X-Y) gives the
MarShaft SCOPE 600 plus 3D 100% 3D functionality.
Complete acquisition of all features
In addition to features such as diameter, length, radii,
and cam location, further features can be measured
with the new 2D probe system that cannot be opti-
cally detected, such as concave cam profi le and axial
run out.
Complete 3D functionality
The tactile and optical measuring systems operate in
the same coordinate system. The measuring station
operates with the software platform MarWin and pro-
vides the complete 3D functionality in this combination.
New:
Due to the implementation of the new software/user
interface "QE Cylindrical Gear" from the MarGear pro-
duct group, blind holes or feather key grooves, tooth-
ing of straight or helical cylindrical gears can now be
measured in addition to camshafts.
The new measurement solution with MarShaft SCOPE
600 plus 3D offers the user several advantages:
The automated measuring method measures much fas-
ter and more reliably: While conventional coordinate
measuring technology requires about 30 to 40 minutes
per workpiece, the Mahr measuring station measures
a gear shaft with cylindrical teeth in just 5-10 minutes.
In addition, the measuring station is directly in pro-
duction near the processing machine for the respective
processing step. The motor abutment ensures that the
workpieces are always clamped with the same clam-
ping force, excluding operator infl uence.
3MarShaft SCOPE 600 plus 3D
1. Performance scope
The product option "Gear measurement on MarShaft
SCOPE 600/850 plus 3D" includes the license for the
MarWin software module "Measurement of Cylindrical
Gears" (QE CYLINDRICAL GEAR). This software module
has the following general features:
• Graphical user interface with interactive elements,
3D view and 3D export
• Automatic storage of raw data
• Various export options (ASCII, QS-STAT, CSV, PDF)
• Connection in MarWin Teach-In processes.*
• Easy transfer of the gear programs from the highly
precise MarGear GMX gear measuring machines
with the MarWin software to the SCOPE plus 3D.
• Complete support of GDE standards
• Complete consideration of the reference end face,
therefore also the automatic protocol and evaluation
adjustment in the case of a dropped measurement
• Evaluation of the axes determined on the component
• Optional automatic elimination of eccentric errors.
• Output of the toothing axis for subsequent
evaluations
• Support for design profiles
• Automatic check of the usability of the probe ball
for the specified toothing
• Support for asymmetrical gears
In MarWin 11.x, this software module in combination
with the MarShaft SCOPE 600/850 plus 3D enables the
following measurements and evaluation on the stated
gear types.
1.1 Straight and helical cylindrical gears as external
teeth and involute profile lines:
• Profile line measurement
• Flank line measurement
• Pitch measurement
• Radial run-out measurement
• Twist measurement
• Topography measurement*
• Feet mark comparison and compensation*
• Evaluation of K-charts*
• Evaluation as per DIN 3960/3962
• Evaluation as per ISO 1328
• Evaluation as per AGMA 2000A88*
• Evaluation as per CAT 1E4157*
• Evaluation as per CAT 1E2028*
• Evaluation as per GOST 1643*
• Evaluation as per AGMA 2015*
Further evaluations/tolerance tables such as GBT 10095,
JIS B1702, RENAULT 01.33.001, VW GEAR STANDARD,
DIN5480, ANSI B92.1 are available upon request. In ad-
dition to the usual gear parameters, it is possible to
convert user-defined measurements in MarWin Profes-
sional. These include, for example, features such as the
gear face chamfer incl. contour evaluation.*
2. Technical data
• Profile features: ffα, fHα, Fα, Cα, Cαa, LCαa, Cαf, LCαf
• Flank features: ffβ, fHβ, Fβ, Cβ, CβI, LCβI, CβII, LCβII
• Pitch features: fp, fpe, Fp, Fp z/8, fu, Rp, Fr, fr
• Maximal accuracy class 5 (as per DIN 3962).
• Machine tolerances as per VDI/VDE 2612 and 2613
Gear Group II
• Measurement of the workpiece always clamped
in the tailstock.
• Smallest stylus diameter: 1mm, smaller diameters
upon request.
• Can be used from machine serial number
2500 and higher.
Software module "Measurement of Cylindrical Gears"Convenient measurement, evaluation and documentation
MarShaft SCOPE 600 plus 3D 4
Example of measuring recordProfessional evaluation and documentation
Comment:
Signature:
MarWin10.50-11
Part:
Welle mit Verzahnung
05.04.201809:24:35
37073 GöttingenDrawing no.: Machining operation:
verchromt
Mahr GmbHCarl-Mahr_Str. 1
1
Inspector:Control 2018
C:/Mahr/Users/Administrator/Temp/temp_Eval.mpr
No. of teeth (z)Normal module (mn)Face width (b)Stylus ball diameter
26 1.8750 mm
22.4500 mm1.0000 mm
Base circle diameter (db)Normal pressure angle (αn)Helix angle (β)Profile shift (x)
54.1425 mm17.5000 ° 32.5000 ° \ 0.3740
Roll path length P/ri
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
µm
FαfHα*ffα
Cαa
Tol.1
4.8 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
0.6 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.2 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 0.6fHαm = 0.6
Gear axis F/ri
18.697
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
µm
Fβ
(1) E
valu
ated
as
per V
DI 2
612
fHβ(1)*
ffβCβ*
K-chart
Tol.1
7.8 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
8.5 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.2 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+ -/-
fHβm = 8.5fHβm = 8.5
Roll path length P/ri
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
µm
FαfHα*ffα
Cαa
Tol.1
4.8 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.9 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
0.6 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
0.0 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.9 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.2 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
9
3.7 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 0.3
Gear axis F/ri
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
µm
Fβ
(1) E
valu
ated
as
per V
DI 2
612
fHβ(1)*
ffβCβ*
K-chart
Tol.1
7.8 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
8.3 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
8.5 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
8.8 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.9 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.2 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.7 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+ -/-
9
+ -/-
fHβm = 8.7
P/ri
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
Tol.1
4.8 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.9 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
4.7 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
0.6 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
0.0 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
1.3 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.9 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
4.3 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.2 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
9
3.7 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
17
4.1 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 0.6
F/ri
17.389
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
Tol.1
7.8 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
8.3 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
7.0 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
8.5 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
8.8 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
7.1 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.9 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
2.8 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.2 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.7 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.2 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+ -/-
9
+ -/-
17
+ -/-
fHβm = 8.1
P/ri
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
Tol.1
4.8 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.9 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
4.7 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
4.7 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
0.6 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
0.0 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
1.3 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
-0.1 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.9 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
4.3 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
4.7 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
4.2 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
9
3.7 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
17
4.1 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
25
3.5 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 0.4
F/ri
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
Tol.1
7.8 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
8.3 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
7.0 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
8.2 [-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
8.5 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
8.8 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
7.1 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
9.0 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.9 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
2.8 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
2.8 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.2 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.7 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.2 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
25
2.6 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+ -/-
9
+ -/-
17
+ -/-
25
+ -/-
fHβm = 8.3
P/le
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
Tol. 1
6.0[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
5.5[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.8[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.8[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 5.5fHαm = 5.5
F/le
9.1979
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
Tol. 1
4.1[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.5[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.9[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.5[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+-/-
fHβm = 2.5fHβm = 2.5
P/le
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
Tol. 1
6.0[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
5.8[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
5.5[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
6.0[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.8[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
3.2[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.8[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.3[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 5.7
F/le
9.6162
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
Tol. 1
4.1[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.1[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.5[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
1.6[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.9[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
1.5[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.5[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.8[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+-/-
9
+-/-
fHβm = 2.1
P/le
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
Tol. 1
6.0[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
5.8[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
5.7[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
5.5[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
6.0[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
7.1[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.8[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
3.2[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.0[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.8[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.3[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.9[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 6.2
F/le
10.406
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
Tol. 1
4.1[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.1[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.0[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.5[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
1.6[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
1.1[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.9[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
1.5[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
1.6[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.5[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.8[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.9[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+-/-
9
+-/-
17
+-/-
fHβm = 1.7
P/le
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb
5:1
Va 1000:1
Tip
Tol. 1
6.0[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
5.8[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
5.7[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
6.2[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
5.5[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
6.0[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
7.1[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
6.7[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.8[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
3.2[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.0[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
3.2[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.8[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.3[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.9[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
25
3.9[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 6.3
F/le
9.883
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb 2
:1
Va 500:1
non-datum face
Tol. 1
4.1[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
4.1[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.0[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
3.6[-/+15.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
2.5[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
1.6[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
1.1[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
2.1[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.9[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
9
1.5[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
17
1.6[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
25
2.4[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1
3.5[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.8[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.9[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
25
4.5[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1
+-/-
9
+-/-
17
+-/-
25
+-/-
fHβm = 1.8
Tol.: DIN 3962 + man. toleranceQnom = 10 + Qman Tol. nOK
Comment:
Signature:
MarWin10.50-11
Part:
Welle mit Verzahnung
05.04.201809:24:35
37073 GöttingenDrawing no.: Machining operation:
verchromt
Mahr GmbHCarl-Mahr_Str. 1
2
Inspector:Control 2018
C:/Mahr/Users/Administrator/Temp/temp_Eval.mpr
Roll path length P/ri
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb 5
:1
Va 1000:1
Tip
µm
FαfHα*ffα
Cαa
Tol.1DOWN_1
4.8 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.8 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.3 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
Roll path length P/ri
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630Roll path length P/ri
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb 5
:1
Va 1000:1
Tip
µm
FαfHα*ffα
Cαa
Tol.1DOWN_1
4.8 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
4.8 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
4.6 [-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.8 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
0.6 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
-2.8 [-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
4.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
5.5 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.3 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
4.2 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
3.8 [-4.5/+4.5]9.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 0.6
Gear axis F/ri
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb
2:1
Va 500:1
non-datum face
µm
Fβ
(1) E
valu
ated
as
per V
DI 2
612
fHβ(1)*
ffβCβ*
K-chartSβ
Tol.1IN_1
10.2 [-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
11.4 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
2.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
0.4 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
+ -/-
1IN_1
Gear axis F/ri
18.697
2.24500
20.2050
2.24500
20.2050
Gear axis F/ri
16.643
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb
2:1
Va 500:1
non-datum face
µm
Fβ
(1) E
valu
ated
as
per V
DI 2
612
fHβ(1)*
ffβCβ*
K-chartSβ
Tol.1IN_1
10.2 [-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
7.8 [-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
6.2 [-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
11.4 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
8.5 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
2.5 [-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
2.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
2.6 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
3.8 [-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
0.4 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
3.2 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
1.3 [-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
+ -/-
1 (0)
+ -/-
1OUT_1
+ -/-
1IN_1 1 (0)
8.98.9 -/-
1OUT_1
fHβm = 8.5
P/le
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb 5
:1
Va 1000:1
Tip
Tol. 1DOWN_1
3.7[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
2.3[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.0[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
2.7[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
P/le
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630P/le
6.15204
12.4107
14.1569
17.0630
6.15204
12.4107
14.1569
17.0630
2 m
m
10µm
Root
Vb 5
:1
Va 1000:1
Tip
Tol. 1DOWN_1
3.7[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
6.0[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
9.9[-/+12.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
2.3[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
5.5[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
13.1[-7.0/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
3.0[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
3.8[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
3.1[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
2.7[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
2.8[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
3.0[-4.5/+4.5]5.5
[] =
Man
ually
ent
ered
tole
ranc
e
fHαm = 5.5
F/le
5.8247
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb
2:1
Va 500:1
non-datum face
Tol. 1IN_1
7.6[-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
8.2[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
1.7[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
4.3[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
+-/-
1IN_1
F/le
9.1979
2.24500
20.2050
2.24500
20.2050
F/le
17.345
2.24500
20.2050
2.24500
20.2050
5 m
m
20µm
datumface
Vb
2:1
Va 500:1
non-datum face
Tol. 1IN_1
7.6[-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
4.1[-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
5.3[-/+15.0][] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
8.2[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
2.5[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
-3.4[-13.0/+13.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
1.7[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
1.9[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
1.6[-/+9.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
4.3[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
3.5[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1OUT_1
1.5[-2.0/+2.0]4.0
[] =
Man
ually
ent
ered
tole
ranc
e
1IN_1
+-/-
1 (0)
+-/-
1OUT_1
+-/-
1IN_11 (0)
11.611.6-/-
1OUT_1
fHβm = 2.5
Comment:
Signature:
MarWin10.50-11
Part:
Welle mit Verzahnung
05.04.201809:24:35
37073 GöttingenDrawing no.: Machining operation:
verchromt
Mahr GmbHCarl-Mahr_Str. 1
3
Inspector:Control 2018
C:/Mahr/Users/Administrator/Temp/temp_Eval.mpr
Continuation of the profile table started on page 1
Left flank Right flank
Continuation of the profile table started on page 2
Left flank Right flank
LCαa
K-chart
Sα
Cαam
Tol.1DOWN_1
3.2 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
1.6 -/-
1DOWN_1
1DOWN_1
LCαa
K-chart
Cαam
Tol.1
2.6 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.0 -/-
1
LCαa
K-chart
Sα
Cαam
Tol.1DOWN_1
3.2 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
2.6 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
2.5 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
1.6 -/-
1 (0)
1.0 -/-
1UP_1
0.6 -/-
1DOWN_1 1 (0)
6.66.6 -/-
1UP_1
1DOWN_1 1 (0) 1
UP_1
LCαa
K-chart
Cαam
Tol.1
2.6 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.5 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.0 -/-
9
1.1 -/-
1 9 Tol.1
2.6 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.5 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
17
2.6 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.0 -/-
9
1.1 -/-
17
1.4 -/-
1 9 17 Tol.1
2.6 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.5 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
17
2.6 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
25
2.3 [-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.0 -/-
9
1.1 -/-
17
1.4 -/-
25
1.4 -/-
1 9 17 25
Tol. 1DOWN_1
3.3[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
0.1-/-
1DOWN_1
1DOWN_1
Tol. 1
2.7[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.2-/-
1
Tol. 1DOWN_1
3.3[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1 (0)
2.7[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1UP_1
2.5[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1DOWN_1
0.1-/-
1 (0)
1.2-/-
1UP_1
3.6-/-
1DOWN_11 (0)
10.810.8-/-
1UP_1
1DOWN_11 (0)1
UP_1
Tol. 1
2.7[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.5[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.2-/-
9
1.2-/-
19Tol. 1
2.7[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.5[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.2[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.2-/-
9
1.2-/-
17
1.0-/-
1917Tol. 1
2.7[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
9
2.5[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
17
3.2[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
25
3.3[-0.9/+0.9]4.4
[] =
Man
ually
ent
ered
tole
ranc
e
1
1.2-/-
9
1.2-/-
17
1.0-/-
25
1.0-/-
191725
Comment:
Signature:
MarWin10.50-11
Part:
Welle mit Verzahnung
05.04.201809:24:56
37073 GöttingenDrawing no.: Machining operation:
verchromt
Mahr GmbHCarl-Mahr_Str. 1
4
Inspector:Control 2018
C:/Mahr/Users/Administrator/Temp/temp_Eval.mpr
Spacing variation
0 2 4 6 8 10 12 14 16 18 20 22 24 26
-2
2
4 Right flank
Tooth no.
fu
Va
5000
:1
2
µm
Single pitch variation
0 2 4 6 8 10 12 14 16 18 20 22 24 26
-2
2
Right flank
Tooth no.
fp
Va 5
000:
1
2
µm
Left flank Table of single pitch variations Right flank
µmActual value
Tol.Qnom
Qact
fpmax fu
max Fp Rp Qual.
1.5[-/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1.6-/-
10
1
[-/-]
[] =
Man
ually
ent
ered
tole
ranc
e
-/-
0 2 4 6 8 10 12 14 16 18 20 22 24 26
-1
1
2 Left flank
Tooth no.
fu
Va
1000
0:1
1 µ
m
0 2 4 6 8 10 12 14 16 18 20 22 24 26
-2
2
Left flank
Tooth no.
fp
Va
5000
:1
2
µm
Left flank Table of single pitch variations Right flank
µmActual value
Tol.Qnom
Qact
fpmax fu
max Fp Rp Qual.
1.5[-/+7.0]
[] =
Man
ually
ent
ered
tole
ranc
e
1.1-/-
10
1
[-/-]
[] =
Man
ually
ent
ered
tole
ranc
e
-/-
5MarShaft SCOPE 600 plus 3D
Easy creation of measuring programs
New, easiest operation of the new MarWin evaluation software "QE Cylindrical Gear". An experienced metrologist
can operate the software after one day of training.
Example of creating a measuring program:
New MarWin evaluation software "QE Cylindrical Gear"Fast and easy operation
Start MarWin Quick&Easy
Start QE Cylindrical Gear
Load gear data, e.g. GED data
Overview of gear parameters
MarShaft SCOPE 600 plus 3D 6
Gear measurement with the MarShaft SCOPE 600 plus 3DYour advantages – Increase of productivity
MarShaft SCOPE 600 plus 3DMarShaft SCOPE 600 plus 3D
You reach a new dimension with the MarShaft SCOPE 600 plus 3D in order to improve the production quality of your
gears and optimize them economically:
• accelerated processes
• increased effi ciency
• fast amortization of the investment
The MarShaft SCOPE 600 plus 3D increases your productivity, thus decreasing your operating costs.
7MarShaft SCOPE 600 plus 3D
Mahr GmbH
Carl-Mahr-Straße 1, 37073 Goettingen, GermanyReutlinger Str. 48, 73728 Esslingen, Germany
Phone +49 551 7073-800, Fax +49 551 7073-888
[email protected], www.mahr.de
Partner of manufacturing companies worldwide.
CLOSE to our customers.
© Mahr GmbH
We reserve the right to make changes to our products, especially due to technical improvements and further developments. All illustrations and technical data are therefore without guarantee.
3764463 | 04.2018
� � ��
Got QUESTIONS? Want more INFORMATION?
Call us at +49 (0) 551 7073 800, or email us at [email protected]