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TPM for lean manufacturing
Chap3. Kobetsu-kaizen for production efficiency
Quote From :TPM Deployment program
TPM encyclopedia Keyword Book
(Japan Institute of Plant Maintenance)
Created by Japanese Gemba Kaizen Web
2
3. Kobetsu-kaizen for production
efficiency
3.1 ・・・ Improvement of zero failure ・・・・・P38
3.2 ・・・ Improvement of the setup ・・・・・P43
3.3 ・・・ Improvement of cutting blade change loss・・・47
3.4・・・ Improvement of start up ・・・・・P50
3.5・・・ Improvement of Minor stoppage ・・・・・P52
3.6・・・ Improvement of Speed losses ・・・・・P56
3.7・・・ Improvement of Yield losses・・P58
3.8・・・ Principle of improvement ・・・・・・P60
“Kobetsu-Kaizen" refers to the “individual
improvement for further efficient
production systems." It means efforts to
select model equipment or a model line
and to challenge the target of zero losses
through project team
activities according to improvement
themes.
“Kobetsu-Kaizen" takes the form of
activities through project teams composed
of managerial staff members and through
small workshop
groups.
The procedures for the implementation of
“Kobetsu-Kaizen" by managerial stall
members are as follows:
[1] Selection of model equipment
Model equipment or a model line should be
chosen.
[2] Organization of a project team
A team of several members should be
organized, with the line manager in
charge of the model equipment serving as its
leader.
[3] Grasping and confirmation of 16 major
losses
[4] Decision on the theme and preparation of a
promotion program
[5] “Kobetsu-Kaizen" project activities
For these activities, failure analysis methods
and IE methods should be
utilized. For chronic losses, PM analysis should
be applied.
[6] Standardization and horizontal evolution
should be completed for enhancement of OEE
3
4
3.1 Improvement of zero failure
3・1・1 Common challenges related to failure
(1) No interest production Section
・ The worker is not anything other than work
・ For safety reasons, worker does not touch the equipment
・ There is no provision
(2) Failure analysis is poor
・They have not drawn broken parts
・ They dose not have to disassemble the defective part
・They only exchange parts
・No relapse prevention
Workers just do not know how to Maintenance
If Teach Maintenance to Wokers ,They can .
Maintenance personnel does not understand the function of the parts
They does not understand Why-Why analysis
5
(3) Maintenance system is incomplete
・Judgment standard ,method of inspection , inspection points is incomplete
・Defective Maintenance schedule
・ Record system of failure
(4) Predictive maintenance is poor
・Periodically measuring equipment to determine the abnormality
・ Precision diagnosis ・・・Measure vibration, current load, timing, operating time,
sound, etc and then understand the change point
If there is no data management can not be right!
6
3・1・2 Thinking reduction of failure
(1) Classification of failure
・failure Classified simple and complex then Give priority to simple failure
・ Method of stratified ・・・Mode causes / line/Occurrence location
(2) Failure analysis
・Stress on the equipment
→ Electric or mechanical stress, temperature, humidity, dust, vibration,
Cause failure :
· deficiencies basic conditions
· Do not keep the terms and conditions
· Degraded without Restore
· lowering skill
· Lack of design
Intensity <Stress
Failure occurrence
To educate and Change the way of thinking
and Change their behavior
3・1・3 Four phases to achieve zero failures
Four phases to achieve zero failures
A short-term and simultaneous implementation
of the five measures for zero breakdowns is
unlikely to progress smoothly. It is more effective
to divide enforcement of the measures into four
phases and implement them one by one under a
plan. Through these steps, steady approach to
zero failures will become possible.
The four phases and principal themes of
individual themes are as follows:
~ Phase 1: To reduce dispersion of MTBF —
mean time between failures.
Repair of previous uncovered but unamended
degradation to restore the original conditions,
preparation of basic conditions, and
prevention of artificial machine deterioration
through observance of usage conditions.
- Phase 2: To extend inherent service life.
Improvement of design shortcomings (corrective
maintenance),prevention of random failure
occurrences due to operation or repair errors,
and restoration by fixing external appearance
deterioration.
- Phase 3: To periodically repair deterioration to
restore original conditions.
Regular deterioration repair to restore the
original conditions
periodic maintenance: TBM), and grasping of
abnormal symptoms
of internal deterioration based on the five senses.
- Phase 4: To foresee the service life.
Prediction of the service life based on condition
diagnosis
techniques (predictive maintenance: CBM), and
technological
analysis of catastrophic failures.
7
3・1・4 Five measures to achieve zero failures
Failures represent only the tip of the iceberg, so
to speak. The leaving of
latent defects below the “water surface" causes
failures.
Methods for uncovering such latent defects and
preventing failures are the
"five measures to achieve zero failures, "and
they are as follows:
[1] Put basic conditions in place:
Keeping of basic conditions for equipment, i.e.,
enforcement of cleaning,oiling, and retightening
(of bolts and nuts).
l2] Abide by operational conditions:
Observance of the specified operational
conditions of the equipment, such
as pressure, temperature, speed, and flow rate.
[3] Restore original functions by fixing
deterioration:
The prevention of forced deterioration of
quipment is possible by preparing basic
conditions and abiding by usage conditions.
Even so,natural deterioration, such as wear,
corrosion, fatigue, and declining insulation,
inevitably occurs. Therefore, such deterioration
should not be left unattended but corrected to
restore the original conditions.
l4] Improve design weaknesses:
Only repeating correction of deterioration cannot
lead to progress. To begin with, deterioration
may be accelerated due to material selection
errors or structural defects during design stage.
Such design shortcomings must be rectified
(this is corrective maintenance).
' l5] "Improve skills:
8
Ask to
the machine
cleaning,oiling, and retightening is Important
9
3.2 Improvement of the setup
This is one of the seven major losses that
impede equipment operations and
refers to the time lost from the
termination of the production of a
present item until the good-quality
manufacturing of the next item
subsequent to setup and adjustment.
The setup here means a series of work:
removal of jigs/tools upon the completion
of the on-going production, clearing up,
cleaning; preparation,attachment,
adjustment, and measurement of
jigs/tools required for the next item
and manufacturing of non-defective
products.
There remain many issues to be
addressed to shorten the time spent
on ‘internal setup’ (setup during
machine stoppage) and ‘external
setup’ (setup without machine
stoppage) based on IE approach.
Adjustment means the following:
[1] Measures to be taken to seek the
optimum solutions or values to attain
some purpose; for instance, the
procedures to put quality within
designed values
[2] What is achieved through the
repetit ion of trial and errors
Understand the setup, to quantify !
10
(1) Organize and tidy
・ Management position of tooling
・ Do not search, do not move
(2) Clarification External setup and Inter
setup
・ Study Elimination of work-
・ Review of work procedures
(3)Study External setup to Inter setup
・Preset(Pre-assembled)
・ Sharing of jig and Exchange one-touch
・ Changes the adjustment to External
setup
・Using the auxiliary jig・・・The elimination
of adjustment
(4) Study procedures of Inter setup
・Study on method of fixation Screw fixing
→ Hydraulic
・ One worker → Two worker Time
savings
(5) The elimination of adjustment
· The purpose of the adjustment
① positioning
② centering
③ the correct dimensions
④ timing
⑤ balance
-Cause of the adjustment
① cumulative error
② shortage standardization
③ shortage rigidity
Analysis of adjustment
Study the one-touch setup
Study eliminating waste of External setup and Inter setup
3・2・2 Improvement of the setup
11
Viewpoint Improvement of setup
5S, preset, standardization, into fixture, no adjustment
12
One-touch attachment and Analysis of adjustment
The elimination of adjustment
→ One-touch attachment
13
3.3 Improvement of cutting blade change loss
3.3.1- Problem of cutting blade
(1)The life of the cutting tool
・Shape and material of the cutting tool
· Cutting conditions (cutting speed)
・Material, hardness
・requirements of Quality product
(Dimensional accuracy, surface roughness)
・Rigidity of the equipment
Look the cutting edge!
14
(2)Exchange conditions
Reason:
・Unclear Exchange standards
・Failure occurs,
Exchange without permission
(3)Inhibiting unattended operation
Reason:
・varies Quality ・Short-cutting tool life
・Occurs Minor Stoppage
(4) Reduction of cutting tool’s cost
・Storing the old chip
・ No management objectives of cost cutting tool
・ Many kinds of cutting tool
・Management chip is loose
・ No historical record use of a chip
・ No Management abrasion of the chip
(Can be use but exchange can not use but No exchange)
15
Detection parameters of the cutting tool life
Quantify sound, vibration, AE, resistance, current, heat
Start-up losses denotes the time losses and
volume losses (from defects and remark)
until product quality stabilizes to
manufacture non-defective products even in
accordance with the specified cycle time
without mechanic troubles, such as minor
stoppages, small troubles, and breakage of
cutting blades, during
[1] start-up after periodic overhaul
[shutdown maintenance]
[2] start-up after downtime (long-term line
stoppage)
[3] start-up after holidays
[4] start-up after the lunch break.
At a machining shop dimension dispersions
are likely to occur during the morning setup,
causing frequent adjustments, rework due to
failure to
adjustment, and breakdown of cutting
blades. To prevent these, warm-up and
idling operations are conducted early in the
morning. The target of
start-up losses is “minimization.”
16
3.4 Improvement of start up
Understanding the thermal displacement!!
17
3.4.2 Improvement Way of start up
(1) measure:
・Measuring temperature of the table, Main shaft, etc to stabilize.
(2) Study Material :
・Consult the manufacturer the material to minimize thermal displacement
(3) Cooling the generator
・ Cool heat by Cooling fan
(4) Automatic correction
・Automatically adjusts to predict beforehand the amount of displacement
Study Cause,Thermal displacement curve,Time to settle
18
3.5 Improvement of Minor stoppage losses
[1] In case temporary functional
stoppage ensues.
[2] in case the recovery of functions is
made by simple fixing
(elimination of abnormal work-
piece and/or resetting)
[3] ln case parts exchange or repair
are not required.
[4] Recovery time lasts from 2 or 3
seconds less than 5 minutes.
Unlike failures, minor stoppage/idling
losses represent a status in
which the machine is subjected
to either stoppage or idling due
to temporary troubles; for
instance, when a work-piece is
clogged in the chute, idling
occurs ; or when a sensor activated
because of a quality defect to
cause a temporary stoppage.
These are the conditions in which the
machine will revert to normal
operation, if the stuck work-
piece is removed, or resetting is
carried out. Therefore, they are
fundamentally different from
machine failures.
To reduce minor stoppages, it is
important to in detail analyze
phenomena [or slight defects]
and to thoroughly eliminate
slight defects.
Observation, analysis, stratified to investigate at the site
19
3.5.2. Improvement Way of Minor stoppage
losses
(1) Phenomenon analysis and motion analysis of workpiece:
Video recording the phenomenon of Minor stoppage , Viewpoint is movement
posture, angle, float, vibration
(2) Remediation of the defect:
Contact surface of the workpiece is key point
Improve the small defects of parts and jigs
(3)Compliance with the basic maintenance:
Cleaning, refueling, retightening
(4) Compliance with of the basic tasks:
Correct operation, setup, adjustment
(5)Study on optimum condition:
Studied the optimization of processing conditions of Parts
(6)Study Weakness:
Studied the problem of the design of equipment、parts,jigs
Understand the movement of the workpiece by video shoot
20
Classification of phenomenon
and Classification of causes
21
22
3.6 Improvement of Speed losses
Into the data to understand the current status of equipment!
One of the seven major losses impeding
efficiency improvement of equipment. These
losses incurred by slow machine speed are
defined as
follows:
[1] Losses due to the difference between the
actual speed and the design
speed (or reference speed for each product
item)
[2] Losses resulting from lower design speed
compared to the present technological level or
desirable speed
(or ‘mission’ speed)
As an example of the former case, the cycle
time is 60 seconds as reference but the actual
operation cycle time is 65 seconds. There is a
speed loss of 5 seconds. As an example of the
latter case, the cycle time is set at 60 seconds
but it could be reduced to 50 seconds through
improvement based on the current
technological level. There is a speed loss of
10 seconds in this case.
Aiming at speed increase would contribute to
clarification of problems and
upgrading of technological levels. Therefore,
the target should be to make
nit the difference between the design speed
and the actual speed.
23
3.6.2 How to improve the speed loses
(1)Understand the cause
To speed up For the experiment.
① Changes in Cp ?
② New bad item ?
③ The life of the cutting tool ?
④ Number of occurrences of Minor Stoppage?
⑤ Percentage occurrence of defective ?
*Examine the aggravating factors measures ahead
(2)Check the validity of the action
①Reduction of air cut time
②Reduction of idle time ③Reduction of operating time ④ Reduction of working hours by two
people work
*Make improvement on equipment mechanism, component structure, timing, the cycle diagram.
Study Air cut time,Idle time,Operating time,Two person work
24
3.7 Improvement of Yield losses
This refers to the volume losses resulting from
differences between raw material weight
and product weight, or between raw
materials input and product weight.
The former represents material losses that can
result from leaving too much iron cast for
fear of casting shortcomings (such as sand
inclusion) or from forging too thick so that it
may be sufficient enough to obtain mold
precision in the shaping process.
As a result of these, cutting time can be
lengthened, or the service life of cutting
blades shortened.
The latter represents the difference between
whitewash weight, gate weight, generated
burr volume and the product weight. in
other words, the losses in this category
result from increased burr generation due
to molding precision insufficiency.
in the case of aluminum casting, this refers to
the
losses representing runner weight and blur
Weight.
25
3.7.2 How to to reduce chronic defects
(1)Immobilization of variable factors
factors?:Impact phenomena logically
Cause?:Which have proved to have influenced the phenomenon
“Restore ,For Immobilizing the "Variation factor"!!
26
3.8 Principle of improvement
27
Thank you for watching the show.
Please read the next chapter at My Home Page
and I hope Like us on Facebook
Regards.
Here my personal site→Japanese Gemba Kaizen Web
my firm site →crane techno consultanting

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TPM For lean manufacturing chp3 | kobetsu kaizen for production efficiency | lean tools

  • 1. 1 TPM for lean manufacturing Chap3. Kobetsu-kaizen for production efficiency Quote From :TPM Deployment program TPM encyclopedia Keyword Book (Japan Institute of Plant Maintenance) Created by Japanese Gemba Kaizen Web
  • 2. 2 3. Kobetsu-kaizen for production efficiency 3.1 ・・・ Improvement of zero failure ・・・・・P38 3.2 ・・・ Improvement of the setup ・・・・・P43 3.3 ・・・ Improvement of cutting blade change loss・・・47 3.4・・・ Improvement of start up ・・・・・P50 3.5・・・ Improvement of Minor stoppage ・・・・・P52 3.6・・・ Improvement of Speed losses ・・・・・P56 3.7・・・ Improvement of Yield losses・・P58 3.8・・・ Principle of improvement ・・・・・・P60
  • 3. “Kobetsu-Kaizen" refers to the “individual improvement for further efficient production systems." It means efforts to select model equipment or a model line and to challenge the target of zero losses through project team activities according to improvement themes. “Kobetsu-Kaizen" takes the form of activities through project teams composed of managerial staff members and through small workshop groups. The procedures for the implementation of “Kobetsu-Kaizen" by managerial stall members are as follows: [1] Selection of model equipment Model equipment or a model line should be chosen. [2] Organization of a project team A team of several members should be organized, with the line manager in charge of the model equipment serving as its leader. [3] Grasping and confirmation of 16 major losses [4] Decision on the theme and preparation of a promotion program [5] “Kobetsu-Kaizen" project activities For these activities, failure analysis methods and IE methods should be utilized. For chronic losses, PM analysis should be applied. [6] Standardization and horizontal evolution should be completed for enhancement of OEE 3
  • 4. 4 3.1 Improvement of zero failure 3・1・1 Common challenges related to failure (1) No interest production Section ・ The worker is not anything other than work ・ For safety reasons, worker does not touch the equipment ・ There is no provision (2) Failure analysis is poor ・They have not drawn broken parts ・ They dose not have to disassemble the defective part ・They only exchange parts ・No relapse prevention Workers just do not know how to Maintenance If Teach Maintenance to Wokers ,They can . Maintenance personnel does not understand the function of the parts They does not understand Why-Why analysis
  • 5. 5 (3) Maintenance system is incomplete ・Judgment standard ,method of inspection , inspection points is incomplete ・Defective Maintenance schedule ・ Record system of failure (4) Predictive maintenance is poor ・Periodically measuring equipment to determine the abnormality ・ Precision diagnosis ・・・Measure vibration, current load, timing, operating time, sound, etc and then understand the change point If there is no data management can not be right!
  • 6. 6 3・1・2 Thinking reduction of failure (1) Classification of failure ・failure Classified simple and complex then Give priority to simple failure ・ Method of stratified ・・・Mode causes / line/Occurrence location (2) Failure analysis ・Stress on the equipment → Electric or mechanical stress, temperature, humidity, dust, vibration, Cause failure : · deficiencies basic conditions · Do not keep the terms and conditions · Degraded without Restore · lowering skill · Lack of design Intensity <Stress Failure occurrence To educate and Change the way of thinking and Change their behavior
  • 7. 3・1・3 Four phases to achieve zero failures Four phases to achieve zero failures A short-term and simultaneous implementation of the five measures for zero breakdowns is unlikely to progress smoothly. It is more effective to divide enforcement of the measures into four phases and implement them one by one under a plan. Through these steps, steady approach to zero failures will become possible. The four phases and principal themes of individual themes are as follows: ~ Phase 1: To reduce dispersion of MTBF — mean time between failures. Repair of previous uncovered but unamended degradation to restore the original conditions, preparation of basic conditions, and prevention of artificial machine deterioration through observance of usage conditions. - Phase 2: To extend inherent service life. Improvement of design shortcomings (corrective maintenance),prevention of random failure occurrences due to operation or repair errors, and restoration by fixing external appearance deterioration. - Phase 3: To periodically repair deterioration to restore original conditions. Regular deterioration repair to restore the original conditions periodic maintenance: TBM), and grasping of abnormal symptoms of internal deterioration based on the five senses. - Phase 4: To foresee the service life. Prediction of the service life based on condition diagnosis techniques (predictive maintenance: CBM), and technological analysis of catastrophic failures. 7
  • 8. 3・1・4 Five measures to achieve zero failures Failures represent only the tip of the iceberg, so to speak. The leaving of latent defects below the “water surface" causes failures. Methods for uncovering such latent defects and preventing failures are the "five measures to achieve zero failures, "and they are as follows: [1] Put basic conditions in place: Keeping of basic conditions for equipment, i.e., enforcement of cleaning,oiling, and retightening (of bolts and nuts). l2] Abide by operational conditions: Observance of the specified operational conditions of the equipment, such as pressure, temperature, speed, and flow rate. [3] Restore original functions by fixing deterioration: The prevention of forced deterioration of quipment is possible by preparing basic conditions and abiding by usage conditions. Even so,natural deterioration, such as wear, corrosion, fatigue, and declining insulation, inevitably occurs. Therefore, such deterioration should not be left unattended but corrected to restore the original conditions. l4] Improve design weaknesses: Only repeating correction of deterioration cannot lead to progress. To begin with, deterioration may be accelerated due to material selection errors or structural defects during design stage. Such design shortcomings must be rectified (this is corrective maintenance). ' l5] "Improve skills: 8 Ask to the machine cleaning,oiling, and retightening is Important
  • 9. 9 3.2 Improvement of the setup This is one of the seven major losses that impede equipment operations and refers to the time lost from the termination of the production of a present item until the good-quality manufacturing of the next item subsequent to setup and adjustment. The setup here means a series of work: removal of jigs/tools upon the completion of the on-going production, clearing up, cleaning; preparation,attachment, adjustment, and measurement of jigs/tools required for the next item and manufacturing of non-defective products. There remain many issues to be addressed to shorten the time spent on ‘internal setup’ (setup during machine stoppage) and ‘external setup’ (setup without machine stoppage) based on IE approach. Adjustment means the following: [1] Measures to be taken to seek the optimum solutions or values to attain some purpose; for instance, the procedures to put quality within designed values [2] What is achieved through the repetit ion of trial and errors Understand the setup, to quantify !
  • 10. 10 (1) Organize and tidy ・ Management position of tooling ・ Do not search, do not move (2) Clarification External setup and Inter setup ・ Study Elimination of work- ・ Review of work procedures (3)Study External setup to Inter setup ・Preset(Pre-assembled) ・ Sharing of jig and Exchange one-touch ・ Changes the adjustment to External setup ・Using the auxiliary jig・・・The elimination of adjustment (4) Study procedures of Inter setup ・Study on method of fixation Screw fixing → Hydraulic ・ One worker → Two worker Time savings (5) The elimination of adjustment · The purpose of the adjustment ① positioning ② centering ③ the correct dimensions ④ timing ⑤ balance -Cause of the adjustment ① cumulative error ② shortage standardization ③ shortage rigidity Analysis of adjustment Study the one-touch setup Study eliminating waste of External setup and Inter setup 3・2・2 Improvement of the setup
  • 11. 11 Viewpoint Improvement of setup 5S, preset, standardization, into fixture, no adjustment
  • 12. 12 One-touch attachment and Analysis of adjustment The elimination of adjustment → One-touch attachment
  • 13. 13 3.3 Improvement of cutting blade change loss 3.3.1- Problem of cutting blade (1)The life of the cutting tool ・Shape and material of the cutting tool · Cutting conditions (cutting speed) ・Material, hardness ・requirements of Quality product (Dimensional accuracy, surface roughness) ・Rigidity of the equipment Look the cutting edge!
  • 14. 14 (2)Exchange conditions Reason: ・Unclear Exchange standards ・Failure occurs, Exchange without permission (3)Inhibiting unattended operation Reason: ・varies Quality ・Short-cutting tool life ・Occurs Minor Stoppage (4) Reduction of cutting tool’s cost ・Storing the old chip ・ No management objectives of cost cutting tool ・ Many kinds of cutting tool ・Management chip is loose ・ No historical record use of a chip ・ No Management abrasion of the chip (Can be use but exchange can not use but No exchange)
  • 15. 15 Detection parameters of the cutting tool life Quantify sound, vibration, AE, resistance, current, heat
  • 16. Start-up losses denotes the time losses and volume losses (from defects and remark) until product quality stabilizes to manufacture non-defective products even in accordance with the specified cycle time without mechanic troubles, such as minor stoppages, small troubles, and breakage of cutting blades, during [1] start-up after periodic overhaul [shutdown maintenance] [2] start-up after downtime (long-term line stoppage) [3] start-up after holidays [4] start-up after the lunch break. At a machining shop dimension dispersions are likely to occur during the morning setup, causing frequent adjustments, rework due to failure to adjustment, and breakdown of cutting blades. To prevent these, warm-up and idling operations are conducted early in the morning. The target of start-up losses is “minimization.” 16 3.4 Improvement of start up Understanding the thermal displacement!!
  • 17. 17 3.4.2 Improvement Way of start up (1) measure: ・Measuring temperature of the table, Main shaft, etc to stabilize. (2) Study Material : ・Consult the manufacturer the material to minimize thermal displacement (3) Cooling the generator ・ Cool heat by Cooling fan (4) Automatic correction ・Automatically adjusts to predict beforehand the amount of displacement Study Cause,Thermal displacement curve,Time to settle
  • 18. 18 3.5 Improvement of Minor stoppage losses [1] In case temporary functional stoppage ensues. [2] in case the recovery of functions is made by simple fixing (elimination of abnormal work- piece and/or resetting) [3] ln case parts exchange or repair are not required. [4] Recovery time lasts from 2 or 3 seconds less than 5 minutes. Unlike failures, minor stoppage/idling losses represent a status in which the machine is subjected to either stoppage or idling due to temporary troubles; for instance, when a work-piece is clogged in the chute, idling occurs ; or when a sensor activated because of a quality defect to cause a temporary stoppage. These are the conditions in which the machine will revert to normal operation, if the stuck work- piece is removed, or resetting is carried out. Therefore, they are fundamentally different from machine failures. To reduce minor stoppages, it is important to in detail analyze phenomena [or slight defects] and to thoroughly eliminate slight defects. Observation, analysis, stratified to investigate at the site
  • 19. 19 3.5.2. Improvement Way of Minor stoppage losses (1) Phenomenon analysis and motion analysis of workpiece: Video recording the phenomenon of Minor stoppage , Viewpoint is movement posture, angle, float, vibration (2) Remediation of the defect: Contact surface of the workpiece is key point Improve the small defects of parts and jigs (3)Compliance with the basic maintenance: Cleaning, refueling, retightening (4) Compliance with of the basic tasks: Correct operation, setup, adjustment (5)Study on optimum condition: Studied the optimization of processing conditions of Parts (6)Study Weakness: Studied the problem of the design of equipment、parts,jigs Understand the movement of the workpiece by video shoot
  • 20. 20 Classification of phenomenon and Classification of causes
  • 21. 21
  • 22. 22 3.6 Improvement of Speed losses Into the data to understand the current status of equipment! One of the seven major losses impeding efficiency improvement of equipment. These losses incurred by slow machine speed are defined as follows: [1] Losses due to the difference between the actual speed and the design speed (or reference speed for each product item) [2] Losses resulting from lower design speed compared to the present technological level or desirable speed (or ‘mission’ speed) As an example of the former case, the cycle time is 60 seconds as reference but the actual operation cycle time is 65 seconds. There is a speed loss of 5 seconds. As an example of the latter case, the cycle time is set at 60 seconds but it could be reduced to 50 seconds through improvement based on the current technological level. There is a speed loss of 10 seconds in this case. Aiming at speed increase would contribute to clarification of problems and upgrading of technological levels. Therefore, the target should be to make nit the difference between the design speed and the actual speed.
  • 23. 23 3.6.2 How to improve the speed loses (1)Understand the cause To speed up For the experiment. ① Changes in Cp ? ② New bad item ? ③ The life of the cutting tool ? ④ Number of occurrences of Minor Stoppage? ⑤ Percentage occurrence of defective ? *Examine the aggravating factors measures ahead (2)Check the validity of the action ①Reduction of air cut time ②Reduction of idle time ③Reduction of operating time ④ Reduction of working hours by two people work *Make improvement on equipment mechanism, component structure, timing, the cycle diagram. Study Air cut time,Idle time,Operating time,Two person work
  • 24. 24 3.7 Improvement of Yield losses This refers to the volume losses resulting from differences between raw material weight and product weight, or between raw materials input and product weight. The former represents material losses that can result from leaving too much iron cast for fear of casting shortcomings (such as sand inclusion) or from forging too thick so that it may be sufficient enough to obtain mold precision in the shaping process. As a result of these, cutting time can be lengthened, or the service life of cutting blades shortened. The latter represents the difference between whitewash weight, gate weight, generated burr volume and the product weight. in other words, the losses in this category result from increased burr generation due to molding precision insufficiency. in the case of aluminum casting, this refers to the losses representing runner weight and blur Weight.
  • 25. 25 3.7.2 How to to reduce chronic defects (1)Immobilization of variable factors factors?:Impact phenomena logically Cause?:Which have proved to have influenced the phenomenon “Restore ,For Immobilizing the "Variation factor"!!
  • 27. 27 Thank you for watching the show. Please read the next chapter at My Home Page and I hope Like us on Facebook Regards. Here my personal site→Japanese Gemba Kaizen Web my firm site →crane techno consultanting