MAINTENANCE BUILDING BLOCKS Maintenance Building Blocks What does
MAINTENANCE – BUILDING BLOCKS
Maintenance Building Blocks? What does it mean and why do you think maintenance base building block important? By definition thesaurus Maintenance - Safeguarding - Protection Base - Foundation – Under pinning base. Building - Structure – Configuration. Block - Parts In other words Protection of Under pinning Configuration or Parts? Why do we need to protect against this basic need.
This presentation is about the work required prior to signing a contracts for the delivery of new equipment. • Another group at the next Roadway Development Workshop will discuss how to manage the new equipment approaching delivery to the mine. • I will be issuing a survey at the end of this presentation to assist with the groups evaluation. Could you return it to Garry Gibson who will forward it to the group.
Acquiring NEW equipment and making a difference. How should I approach the exercise. An essential tool is Project Management - Front End Loading? Front-End Loading (FEL) is a term used to describe the activities undertaken during the project planning phases & prior to a project commitment being made. o Its about getting it right from the inception of the process before you get to a point where it is much harder and more costly to rectify issues. o. I t is all about doing the work upfront, understanding the issues, during the design phase because o There is never a better time to get it right than before you fully engage the O. E. M or start cutting the steel. Never are we in a better position to bargain? o How long do you think it should take to get things right.
Theory of Constraints • It is an approach to solve constraints and problems in a logical way by building a logic chart of the problem, finding its roots and developing steps to remove the root of the problem. • So how do I understand the logical problems find the root cause and remove it. • It is too late after the equipment is designed and delivered to complain about something that is not right.
1. Do I understand what it is I need / want? • Have I canvassed/consulted with all interested parties particularly the end users. • Have I scrutinised the mine constraints to allow a seamless introduction of the new equipment. • Have I intimately scrutinised my process to accept / maximise the impact of my new equipment. • Do I understand what it is I want from the machines productivity. • Does any of my existing system or equipment constrain my new equipment. SC, Feeder, Ventilation etc • Can I see the new machine in action at another operation, is their process similar to my process. • Can I modify my process to maximise the benefits of the new equipment. • Do I understand the equipment fundamental design constraints. • Is there a consolidated accepted document identifying all my needs and wants? • Have we evaluated all potential alternatives and technologies?
2. DOES THE O. E. M know understand what I need / want • Have I conveyed my needs and wants to the O. E. M in a concise and well documented manner. • Does the O. E. M know / understand how I will operate the equipment and what my targets are? Be reassured the designer / supplier cannot design anything he is unaware of. • • • Is the O. E. M able to deliver my needs and wants, are we fundamentally aligned. Given enough time they should be able to deliver. Is the O. E. M cooperative enough to work through our fundamental differences to achieve my goals. Do I have a detailed specification or position that binds the O. E. M to my needs. Is there enough measures in my documentation to ensure what I have asked for is being delivered in the equipment. Does the O. E. M have enough time to deliver my needs / wants within the timeframe I allow him. Unrealistic times lead to trade offs. Have we formulated a partnership with the O. E. M in delivering our equipment. It should not be adversarial.
• DESIGN IS THE BREAD AND BUTTER TO RELIABILITY You can only manage what you understand, if you don’t ask for detailed design information, you wont receive, be convinced that adequate design information exists in a current form. • Quite often we have tolerated rather than eliminate design issues or if it is new equipment we may not even know. • The equipment you accept will reflect the design issues inherent with the machine and will be the downtime and maintenance requirements you have to manage in the future. • Your ongoing maintenance tolerance will be affected by the lack of a sound DFMEA during the design phase. • Understanding machine productivity needs, must be reflected in any maintenance plan. • Without equipment productivity none of us have a job, maintenance and production must coexist and work towards the consolidated effort, it is not a trade off.
DESIGN IS THE BREAD AND BUTTER TO RELIABILITY • All equipment will prior to installation at a Mine have completed a comprehensive design DFMEA (Failure Mode & Effects Analysis) to determine the equipment limitations or failure modes. • All safety critical components will be identified and their design criteria documentation be available and understood by the end users. • Safety Critical components will have a safety integrity level defined commensurate to the hazards evident. • Design information will be confirmed by a person with expertise and experience within the field of design. • All modifications or re design will incorporate as a minimum a design FMEA. • Design Information will be available on site within quality documentation. • Equipment Design Limitations will be formally communicated with end users. • Design will be reviewed for optimal ergonomics and require minimal human intervention. • Design should where possible automate the equipment to optimum equipment reliability and productivity and therefore eliminate constraints.
GETTING A LOOK AT THE FINAL PRODUCT BEFORE THE SPECIFICATION EVOLVES – 3 D
GETTING A LOOK AT THE FINAL PRODUCT BEFORE THE SPECIFICATION EVOLVES – 3 D YOU HAVE NO EXCUSE TO SAY I DID NOT KNOW THAT!
Why do I need to know about Component Life Cycle - Bolter Life Cycle Item Part No. Quantity on ABM Description Component Lifecycle Consumable Lifecycle Min Max 25000 70000 2500 12500 5000 25000 70000 2500 12500 7500 2500 1 2 ZG 1 CF 005 - LH ZG 1 CF 005 - RH 2 2 Roof Bolter Frame Assembly 3 ZP 102200 8 Retainer, Carriage Assembly 4 ZG 102200 4 TJ Cylinder Rod Assembly 5 ZG 201200 4 Telescopic Feed Cylinder 6 ZG 201001 4 Roof Bolter Carriage Assembly 7 ZP 201112 16 Drill head Retainer 8 ZG 201145 8 Drive Chain 9 ZG 201143 16 Pulley 10 ZP 201107 8 Drive Chain Adjuster Bolt 2500 7500 11 ZP 201301 4 Drive Chain Anchor Block 2500 7500 12 13 BM 804000 - LH BM 805000 - RH 1 1 Roof Bolter Mount 25000 70000 14 JC 300882 -004 2 FOR/AFT Tilt Cylinder Inner 125000 15 JC 345872 -001 2 IN/OUT Tilt Cylinder Outer 125000 16 JC 300882 -005 2 For/Aft Tilt Cylinder Outer 125000 17 ZP 308000 2 Gripper Jaw Head plate 18 DP 464300 4 19 ZP 300100 4 20 21 ZRB 1 CF 000 - LH ZRB 1 CF 000 - RH 1 1 Rib Bolter Frame Assembly 22 ZRP 100030 4 Retainer, Carriage 23 ZRP 100040 2 Inlet Block 24 ZRB 100100 4 TJ Cylinder Assembly 25 ZRB 200100 2 Telescopic Feed Cylinder Assembly 26 ZRB 200000 2 Rib Bolter Carriage Assembly 27 ZRP 200212 4 Drill head Retainer 28 ZRB 200145 4 29 ZRP 200143 8 30 ZP 201107 31 ZRP 200201 From a maintenance perspective less worried must be more reliable High maintenance less reliable, interests me greatly 25000 70000 Gripper Jaw Cylinder 125000 Gripper Jaw 500 25000 70000 2500 125000 70000 5000 25000 70000 2500 12500 Drive Chain 2500 7500 Pulley 2500 12500 4 Drive Chain Adjuster Bolt 2500 7500 2 Drive Chain Anchor Block 2500 7500 Obviously things don’t last for ever Why is there 2 values? variable equipment conditions, maintenance efforts or they don’t understand equipment life cycle
So what happens when we get it wrong? • An earlier experience I understood about the purchase of some low height CM & SC. • Purchasing equipment that is too big to fit in mine • Things change how does 125 tonne concrete block vibrate excessively.
DESIGN – What is it and how does it affect EQUIPMENT PERFORMANCE? Your system is perfectly designed to give you the results that you get. W. Edwards Deming 15
ONGOING EQUIPMENT PERFORMANCE? What happens if we get it wrong SO WHAT HAPPENS WHEN WE ONGOING DESIGN ISSUES? We need to work out what it is the root cause. It not always easy to determine the root cause. What tools can we use to determine the cause? 16
DESIGN – What is it and how does it affect EQUIPMENT PERFORMANCE? So what do we need to do? UNDERSTAND WHAT THE DESIGN CRITERIA IS AND IF YOU DON’T FIND SOMEONE WHO DOES? INGORANCE IS NOT BLISS AND IS THE PROBLEMS THAT YOU CONTINUE TO ACCEPT HAVE CHECKS AND BALANCES IN PLACE FROM CONCEPTUAL DESIGN - RETIREMENT! MAKE SURE YOU UNDERSTAND ALL POTENTIAL LOADINGS, OPERATING CRITERIA, KNOW YOUR EQUIPMENT NEEDS? DEMAND AN EXHAUSTIVE QUALITY ANALYTICAL PROCESSES FOR DETERMINING DESIGN ADEQUACY! WHEN YOU THINK ITS RIGHT CHECK AGAIN ITS THAT IMPORTANT, MISSED DESIGN OPPORTUNITIES IS YOUR FUTURE ENGINEERING PROBLEMS!
DESIGN – What is it and how does it affect EQUIPMENT PERFORMANCE? AFTER THE DELIVERY IT CAN STILL BE DONE BUT AT A GREATER EXPENSE AND INCONVENIENCE Performance Analysis using the FMEA Model Major “Failure Modes” That Result in Production Losses? Frequency of Occurrence of Each? Typical Effect & Consequence in Units or $? Any Extraordinary Repair Costs? Preliminary View of Causes of These Failures? Preliminary Priorities for Action? 18
CONDITION MONITORING – DIAGNOSTIC TOOLS OR BLACK MAGIC? CONDITION MONITORING OR A RELIABILITY ENGINEER CONDITION MONITORING IS A TOOL TO MONITOR FOR THINGS THAT ARE GOING WRONG OR MAYBE HAVE ALWAYS BEEN WRONG 19 (DESIGN IS THE TOOL FOR ELIMINATING ONGOING WRONGS. )
SOME DISCUSSION POINTS
Other Plant Breakers, Fan, DCB, etc; 71; 4% Panel Conveyor; 185; 10% Panel Conveyor; 70. 57; 5% Other Plant Breakers, Fan, DCB, etc; 216. 055; 15% Shuttle Cars; 279; 14% Continuous Miners (Ecl Hyd for rigs); 1052; 54% Roof & Rib Bolters (Inc Hyd hoses for rigs); 353; 18% Roof & Rib Bolters (Inc Hyd hoses for rigs); 177. 9; 13% Panel Conveyor; 141. 265; 11% Other Plant Breakers, Fan, DCB, etc; 161. 05; 12% Continuous Miners (Ecl Hyd for rigs); 719. 08; 51% Shuttle Cars; 231. 17; 16% Continuous Miners (Ecl Hyd for rigs); 521. 19; 40% Other Plant Breakers, Fan, DCB, etc; 386; 14% Panel Conveyor; 249; 9% Continuous Miners (Ecl Hyd for rigs); 1180; 44% Shuttle Cars; 496; 19% Shuttle Cars; 306. 375; 24% Roof & Rib Bolters (Inc Hyd hoses for rigs); 161. 605; 13% Roof & Rib Bolters (Inc Hyd hoses for rigs); 369; 14%
Other Plant Breakers, Fan, DCB, etc; 203; 5% Panel Conveyor; 613. 6; 16% Continuous Miners (Ecl Hyd for rigs); 1695. 4; 44% Other Plant Breakers, Fan, DCB, etc; 340. 89; 9% Panel Conveyor; 61; 2% Shuttle Cars; 654; 17% Continuous Miners (Ecl Hyd for rigs); 2034; 54% Shuttle Cars; 564. 80999999; 14% Roof & Rib Bolters (Inc Hyd hoses for rigs); 817; 22% Roof & Rib Bolters (Inc Hyd hoses for rigs); 674. 55; 17% Panel Conveyor; 294. 46; 15% Other Plant Breakers, Fan, DCB, etc; 182. 25; 9% Panel Conveyor; 294. 44; 10% Continuous Miners (Ecl Hyd for rigs); 662. 64; 34% Other Plant Breakers, Fan, DCB, etc; 569. 49; 19% Shuttle Cars; 260. 24; 13% Roof & Rib Bolters (Inc Hyd hoses for rigs); 572. 75; 29% Shuttle Cars; 485. 70; 17% Continuous Miners (Ecl Hyd for rigs); 1081. 08; 37% Roof & Rib Bolters (Inc Hyd hoses for rigs); 501. 19; 17%
0. 00 Feb-09 Jan-09 Dec-08 Nov-08 Oct-08 Sep-08 Roof & Rib Bolters (Inc Hyd hoses for rigs) Aug-08 Jul-08 Jun-08 May-08 Apr-08 Mar-08 Feb-08 Jan-08 Dec-07 Nov-07 Oct-07 Sep-07 Aug-07 Jul-07 Jun-07 May-07 Apr-07 Mar-07 Feb-07 Jan-07 Continuous Miners (Ecl Hyd for rigs) Shuttle Cars 120. 00 100. 00 80. 00 60. 00 40. 00 20. 00
- Slides: 23