Current Efficiency (Final) - Dubai Quality Group

3 • Smelting converts alumina (ore) into aluminum metal through electrolysis process ―By using Direct Current (DC) ―Current Efficiency (CE) is the rat...

155 downloads 550 Views 3MB Size
Increase Current Efficiency of Potline 3 (P/L-3)

Introduction Dubai Aluminium Company Limited (DUBAL) •

Based in Jebel Ali, Dubai



Annual Production of > 1 million tonnes of aluminium



>4000 Employees



8 Potlines consisting of 1573 aluminium cells



One of the few smelters in world to produce primary high purity metal for use in electronics and aerospace industries.

2

Project Background • Smelting converts alumina (ore) into aluminum metal through electrolysis process ― By using Direct Current (DC) ― Current Efficiency (CE) is the ratio of electrical direct current that results in actual metal production • Therefore, improvement in Current Efficiency remains one of the strategic objectives of any Aluminium smelter

3

Define Phase

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Problem Statement: •

Potline 3 Current Efficiency is at 92.9% for H1 2009 which is below target since increase of current amperage to 200 kA,



resulting in decreased plant hot metal output.

Project Target: Increase average Potline 3 current efficiency to target of 93.1% for 2010.

4

1. Define

2. Measure

3. Analyze

4. Improve

Project Scope: In Scope:

Out of Scope:

Potline 3 Process Parameters and Procedures

All other Potlines

Unit of measurement: 

Potline 3 Current Efficiency

Operational Definition: 

Monthly Average CE from iRPMS (Smelting Database System) 5

5. Control

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Team Charter: S.No

Name

Functional Role

Project Responsibilities

1

Daniel Whitfield

Manager – Projects D18

Team Leader.

2

Andries Louw

Snr Process Control Engineer – Potrooms

Data analysis and report making.

3

Mohamed Tawfik Boraie

H.O.D: PC-CL

Data analysis and report making.

4

Saif Mohamed

Snr. Planner – Prodn Services

Data analysis and report making.

5

Najeeba Al-Jabri

Snr Manager

Data collection and implementation of solutions.

6

Tariq Majeed

Supt Potroom Operations

Data collection and implementation of solutions.

7

Devadiga H.R.

Act, Manager, Line 3, 7 & 9

Data collection and implementation of solutions.

8

Maryam Al-Jallaf

Snr. Manager - PC PR & CL

Data collection and implementation of solutions.

9

Adam Sherrif

Snr Process Control Engineer – Potrooms

Data collection and implementation of solutions.

6

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Stake Holder Model : ARMI Chart Approver VP-Smelter Ops.

Resource

Member

Interested Party

Manager D-18

Andries Louw

VP-Casthouse

P/L-3 Superintendent

Mohamed Tawfik Boraie

VP-Marketing

P/L-3 Technicians

Saif Mohamed

VP-Finance

P/L-3 Operators

Najeeba Al Jabri

VP-Power & Desal.

P/L-3 Process Technician

Tariq Majeed Devadiga H.R. Maryam Al-Jallaf Adam Sheriff

7

1. Define

2. Measure

Project Schedule

8

3. Analyze

4. Improve

5. Control

Measure Phase

1. Define

2. Measure

3. Analyze

4. Improve

5. Control



Current efficiency is key measure of process performance, and is regularly reported and monitored



It is difficult to be measured directly; therefore, inferred from actual metal production as below:

Current Efficiency



Actual Hot Metal Production = -------------------------------------Theoretical Hot Metal Production

Three months average taken to ensure reasonable accuracy of the data

9

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Measurement System Analysis •

Actual Metal Production =Total Weight of Metal delivered to Casthouse  Casthouse scales regularly calibrated and checked – Verified Calibration Records and is OK



Theoretical Metal Production = f (Amperage supplied by Power Plant)  Power Plant amperage supply tested on monthly basis – Found Ok



Review of existing plant system for measuring and reporting current efficiency showed no significant concerns over accuracy or precision

Measurement System – Found Satisfactory

10

Analyze Phase

1. Define

2. Measure

3. Analyze

Current Efficiency – Back Reaction Flow Chart Carbon Dusting

Anode Spike

Cell Overfeeds

Excessive Sludge

5. Control

Tool (s) Applied:

Current bypasses electrolyte

Cell Becomes Unstable

4. Improve

-

Process Flow Diagram

Excess heat generation

Low Bath Temp / High AlF3

Al solubility in bath increases

High Bath Temp / Low AlF3

Cell Underfeeds

Excessive Anode Effects

Bath Height Too Low

Excessive Anode Airburn

BRSP Set too low

Cell ACD Reduced

Al mixes back into electrolyte

Oxidation of Al to Al2O3

Low Current Efficiency

Possible causes for low Current Efficiency         

Bath temperature/AlF3 Age Anode Effects Alumina Feeding Metal and Bath height Base Resistance Set Point (BRSP) Noise/stability 11 Operational problems Anode Problems

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Tool (s) Applied: Multi-Variable Linear Regression • In multi-variable linear regression, there are several independent variables up to N. Yi = βo + β1xi + β2xi + … where

i = 1, …. N.

• P-value shows the significance of the correlation (p-value of 0.05 = 95% statistical significance or confidence). As much P-value closer to 0.0 as much as the parameter is statistically significant

• Strongest correlation between bath temperature and AlF3 (interrelated variables) Needs more investigation

• Age refers to life of reduction cell, and hence it is an unassignable cause

Variable Bath Temperature AlF3 Age AEF TRSP UF Duration Time Unstable Dumps BRSP Metal Height Bath Height Average Resistance Volts 12 Noise

P-value 0.000 0.034 0.038 0.066 0.094 0.275 0.305 0.451 0.537 0.554 0.583 0.608 0.736 0.746

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Bath Temperature •

Based on accumulative experience, it is proven that increase of 5oC in bath temperature can lead to 1% drop in current efficiency 976

Linear regression covers the relationship:

974

CE = (-0.2259 x bath temperature) + 309.13 (R2= 0.9543)

Bath Tem perature (C)

972 970 968 966 964 962 960 84

86

88

90

92

94

Current Efficiency (%)

96

98 13

100

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Base Resistance Set Point (BRSP) •

Relationship between BRSP/ACD and CE well established

• Initial analysis looked BRSP and CE. No big correlation above ~14.75 µ

• Some correlation < 14.75 µ 100

C u rren t E fficien cy (% )

98 96 94 92 90 88 86 84 13.5

14.0

14.5

15.0

15.5

BRSP (micro-ohms)

14

16.0

16.5

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Poor Performing Cells Tool (s) Applied: Cumulative chart 100%

Loss of Current Efficiency (% )

90% 80%

~20% of cells represent 47% of total CE loss (Actual CE – Target CE).

70% 60% 50% 40% 30% 20% 10% 0% 0%

10%

20%

30%

40%

50%

60%

70%

80%

90%

Number of Cell (%) 15

100%

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Validated Root Causes/ Parameters

×



Root Cause 1: High Bath Temperature



Root Cause 2: Low Base Resistance Set Point (BRSP)

Age – Life of Cell: Difficult to address this cause

16

Improve Phase

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Root Cause 1: Action plan for high bath temp and low CE pots S. No.

1

Action Point

Responsib ility

Completion Date

Adjust Bath Chemistry to improve Current Efficiency

Daniel Whitfield

Dec. 2009

Current Efficiency Vs Bath Temp 95.0 y = 0.052x + 92 R2 = 0.6879

966

94.0

964

93.5 962 93.0 960 92.5 92.0 91.5

958 Bath Temperature Current Efficiency Linear (Current Efficiency)

956

91.0

954 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 Week No. (2009 - 2010)

1

3

17

Bath Temp (°C)

Current Efficiency (%)

94.5

968

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Root Cause 2: Action plan for low Base Resistance Set Point (BRSP) • •

Established Control Limits so that BRSP not to be lowered below 14.5 µ without careful monitoring of the current efficiency Critical BRSP Limit of 14.75 µ.



Increased the BRSP in low CE/BRSP cells



Example of “action plan for implementation” as a result of weekly meetings is given below

Cell 146 198 271 149 117 102

CE - 4wks CE - 16wks CE - 52wks Action Person Target Date Increase BRSP by 0.1µcheck dumpweight AS/MSW 07/01/2010 89.3 90.6 92.9 90.3 91 92 Check BFT, Cu tab and dumpweight MSW 10/01/2010 92.5 91 91.9 Improving in last 28 days, no action 20/01/2010 Increase BRSP by 0.05µcheck Cu tab 89.3 91.1 93 MSW 07/01/2010 92 91.2 90 Under Fe attack FM NA Increase BRSP by 0.1µ 93 91.3 91.5 AS 07/01/2010

• Average increase of 0.34 µ in 25 cells, average increase of 1.5% CE

18

1. Define

2. Measure

3. Analyze

4. Improve

5. Control

Current efficiency after improvement actions 95.5

201 Project Start

200

94.5

199

94.0

198

93.5

197

93.0

196 Monthly CE

92.5

3-month Running Average Target CE

92.0

195 194

Amperage 91.5 7 -0 v No

193 08 n Ju

08 c De

9 -0 l Ju

10 n Ja

10 g Au 19

11 b Fe

11 p Se

Amperage (kA)

Current Efficiency (%)

95.0

Control Phase

1. Define

2. Measure

3. Analyze

5. Control

4. Improve

System established for identifying and improving poor CE cells •

List of poor performing cells in Potline 3 developed, updated and released on weekly basis for setting up proper action plans.



Work Instruction was developed to diagnose and action poor performing cells Before the project

After the Project

Summary forof L3L3 CE, June 2009 Distribution CE, June 2009

Summary for 2010 Distribution ofL3 L3CE, CE,Feb Feb 2010

84

Sample size Mean STD. Dev.

87

90

93

96

86

88

227

227

Difference

92.32 %

93.70 %

+1.38%

2.47 %

1.71 %

-0.76%

90

20

1st

Quartile

91.4 %

92.7 %

+1.3%

92

94

96

98

1. Define

2. Measure

3. Analyze

4. Improve

5. Control



Potline 3 monitoring on daily basis by Potline Engineers and Technicians through potroom monitoring and reporting system (Smelter Analytics)



Fine-tuning and changes to pots operating targets

21

C u rre n t E f f ic ie n c y ( % )

Project Success & Benefits 94.2 94 93.8 93.6 93.4 93.2 93 92.8 92.6 92.4 92.2

Actual CE% Target CE%

 Increased average Potline 3 current efficiency

 Improved overall Potline performance 2009, 2nd Half

2010, 1st Half

2010, Full year

2011, YTD

 Project yielded re-occurring financial benefits of AED 1.47 millions per annum 22

Project Closure Learnings and Roll-over: •

Documentation of the project report



Use of statistical tools and gained better understanding w.r.t. Smelting Process



Roll-over of the successful initiatives from projects – to sister Potline 1 – Achieved similar increase in current efficiency

Recognitions: •

All team members received gift and cash award



Project selected for Share Best Practice Session – to 200+ employees



Nominated for CII Symposium 23

Why this Project is an Excellent Improvement Example? •

Achieved one of the best current efficiencies in D-18 type of cell design (at higher Amperage of 200kA)



Combination of technical as well as statistical methods by using DMAIC approach



Project experiences rolled-over to Potline of similar cell design and resulted in improvements



Quantum contribution to company’s process performance



Environmentally beneficial

24

Thank you

25