The document discusses VA/VE (value analysis/value engineering) support provided by Hero Motors (HM) to optimize design and processes, increase efficiency, improve customer satisfaction, and enhance profitability. It outlines HM's VA/VE implementation process and provides examples of design optimization, testing facilities, process optimization, and cost savings achieved through modifications to transmission and housing components.
1. VA/VE Support By HM
Following the engineering approach
For
Cost Saving
Customer Satisfaction
2. VA/VE Support in HM
The Goal
Optimize the Design & Process
Increase Efficiency of process
Customer Satisfaction
Support to Customers Problems
Less ECN
Enhance Overall Profitability
Establish ‘Savings Culture’
Prepare Organization for the Future
Reduce Complexity
3. VA/VE Support in HM
The VA/VE Implementation Process
Hero Motors
Customer Implementation
Customer
Satisfaction
4. VA/VE Support in HM
1. HML’s design and optimization process – with a case study
2. Technical Assistance Agreement with Ricardo India.
3. HML’s Manufacturing and End-Of-Line testing facilities with emphasis on
Quality Assurance.
4. HMCL’s 100 cc transmission parts under consideration and business
strategy
Highlights
5. VA/VE Support in HM
Design Support
PRO/e WF-3
Kissoft3-2008
Alias 12.02
Imageware-11
Icem srf4.3
Design Optimization
Design validation
Testing Facility
NVH Testing
Mechanical Testing
Reverse Engineering
Process Optimization
Highlights
7. Duty Cycle
System level Misalignment, TE
Transmission Spec
Safety factors and durability assessment of
Gear, Shaft & Bearings Reliability Growth test
System level Accelerated
Test
Durability test on rig
In Vehicle durability
test
Transmission Design - Flow down
Based on Transmission specifications and vehicle class, detailed targets for gear,
bearing and shaft durability, NVH and product testing specification were
developed.
8. Benchmarking – To set weight and cost targets (up front
in design cycle)
0
20
40
60
80
100
120
140
160
180
70 71 72 73 74 75 76
Torque(Nm)
CD
Torque Vs CD72 mm CD is appropriate to
transmit 100 Nm torque and
can potentially meet all
future variants like wider
ratios, future torque increase
in same engine family or
sporty application.
- 6.5 Kg is set as target
weight of input and out put
shaft assembly with bearings.
Data :
- Seven Spur and a helical transmission for
engines ranging from 790 cc to 1600 cc
- Max 1st ratio 2.9 and min 2.29
- Max 5/6th ratio 1.04 and min 0.67
9. Concept - transmission with Helical Gears
- All helical gears (except 1st) with varying helix angle to balance axial load on bearings and to make
transmission compact.
- Module ranging from 2.475 mm to 2.0 mm with CD 72 mm for 100 Nm torque engine.
- One gear is integral part of shaft in the middle to reduce gear misalignment.
- Helical gears transmit higher torque with less weight along with reduced NVH
10. Base line NVH before optimization
Appropriate
manufacturing
process is
selected and
micro geometry
parameters
selected based
on these results.
Hobbed gear Ground gear
11. Micro geometry parameters like profile crowning, slope, tip relief were chosen and optimized while
applying production variations and set of torques loads on selected parameters.
Mating Gears micro Geometry Optimization
12. Mating Gear transmission error and effect of load sharing
among teeth
Smooth and gradual load
transfer from one teeth to
another
Resulting smooth transmission
error. As a result, tooth
excitation force will be minimum
while transferring torque.
14. NVH Optimization - Summary
Hero motors can study system level dynamic effects on gear trains by
analyzing effects of bearing, housing, shaft on gears. This analysis guides us to
optimize micro geometry to reduce effect of gear misalignment, gear dynamic
effects and NVH. In one optimization loops, final results can be achieved.
Moreover, Hero motors also provide proto samples using KAPP grinding
machine with universal vario dresser. This will help Customer to validate micro
geometry before implementing in production and also guide customer to
foresee effects of micro geometry variations on NVH during production.
15. End of line testing : Transmission shaft Assembly
End of line checking: Complete gear sets, shifting all gears:
16. Engine Power :- 67 kw at 7250 RPM
Max Torque at Input:-250Nm
Max torque at output:-1400Nm
Gear Ratio:-
High:- 0.75
Low:-0.43
Reverse:-0.35
Bevel gear –0.40 (Apply to all gear
additionally)
Specification
1010 Gear box introduction
19. 810 SHO LH housing Study
Existing assy Proposed assy
Proposed cost saving
present cost Cost saving
1.Support flange removal and modification in hsg 19.84 19.84
2. 2-nos screw removal (For support flange mtg) 2.63*2 5.26
3. 2-nos dowel pin removal (For support flange) 4.88*2 9.76
4. Reduce time in Assy
5.Housing modification vendor feedback reqd.
Total cost saving Rs34.86/assy
Annual cost saving @30000 volume /yr 10.45 lac/yr
Support flange
screw
20. 810 SHO LH Housing modification proposal
Existing Housing Proposed Housing
Removing these bosses For index lever
mtg
For shift drum assy mtg
Relieve for
intermediate
gear
For index
lever spring
stopping
21. 1403Gear Box study
For positive locking for shaft and plate, we can lock it by making serration into both parts
Thus machining can be avoided for shaft and plate.
22. 1403 Gear Box study
This cap can be eliminated by non machining of end of the shaft to stop coolant flowing through
the shaft
23. 1403 Gear Train-Manufacturing problem
These all picture shows possibilities of problem in mfg when considering tolerances on root diameter
,needs to be studied by Rotax and from HERO
910435230
910435190
24. + =
New designed circlip
Rotax 991 VA/VE proposals
1.Replacing these spline bushes with
split needle bearing so that Spline
machining length would be reduced
Mass removing by making ring groove to be
made in forging itself
They are using circlip and spline washer to
restrict the gears. We have propose to use new
designed circlip that will do the same function
Can be bom saving and assy time saving
proposals
1 2
25. P art
S .
No.
P roblem Root C aus e P ropos al D-II D-III S tatus
1 M10 Blow Hole
E xcess machining allowance
in casting
P rovide C ore hole in C asting. Yes Yes
C ore Pin added in D-II.
Implemented
2
M10 Blow Hole on
F ace of C ounter
E xcess machining allowance
in casting
P rovide C ounter in C asting. No Yes
EC R sent to Rotax.
Approval awaited.
Dowel (2) Blow Hole
Ø47.5 OD Blow Hole
Ø8.7 - LH - Blow
Hole
5
4
Yes
E xcess Machining allowance
in casting
No Yes
C hange Resting, C lamping &
Locating P ads in C asting &
Remove E xtra Material in
C asting.
E xcess Machining allowance
in casting. Throug h this
chang e we can s ave
Material, Maching C ycle
Time & R ejection of C entre
Hs g with R H Hs g
No
Yes
No
Yes
No
R H Hous ing C omponent Des ign C hanges
Outer Radius change to sharp
edge
E C R approved by
Rotax.
E C R approved by
Rotax.
7
Ø90 Blow Hole3
6
Ø8.7 - RH - Blow
Hole
F ace Blow Hole on
Gasket F ace
P rovide C ore hole in C asting.
E C R approved by
Rotax.
S olid casting change to as
cast core hole
Radius at outer profile on
face. Due to this face blow
hole problem occur & parting
line of insert is below the
radius.
EC R send to Rotax.
Approval awaited
8
E C R Approved by
Rotax.
Yes
Yes
EC R sent to Rotax.
Approval awaited
Many small chamfers & radius
on F ix S ide for which C ore
P ins are provided on both fix
and moving side due to which
casting frequently stuck on F ix
side.
E xcess Machining allowance
in casting
10
Dia 15.7&M14 C ore hole to
be made by providing the
core pin from moving side
Both side (F ix & Moving S ide)
core hole change to one side
(Moving S ide)
Yes
9
No
F requent C asting
J am in fix side
during P roduction
1
6
5
2
4
3
7
9
10
8
Process Optimization