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Field Demonstration of New and Improved Parts Cleaning Systems. Productivity, Reliability, Availability, and Maintainability (PRAM) Program. Objective. Identify and evaluate recent APW technology advancements to improve the overall USAF parts cleaning capability and reduce manpower requirements for cleaning while continuing to meet environmental metrics..
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1. Aqueous Parts Washers Rick Miles, Ph.D.
NCI Information Systems, Inc.
811 Park Drive
Warner Robins, GA 31088
rmiles@nciinc.com
Phone: (478) 975-0744
Fax: (478) 975-0756
3. Objective Identify and evaluate recent APW technology advancements to improve the overall USAF parts cleaning capability and reduce manpower requirements for cleaning while continuing to meet environmental metrics.
4. Project Goals Demonstrate that with the proper engineering analysis being performed upfront, the automatic aqueous cleaning process is a viable replacement for most solvent cleaning systems.
Eliminate the need for supplemental cleaning operations and all corrosion problems associated with the aqueous cleaning process.
Address the problem of hazardous waste generation from aqueous cleaning processes.
5. Deliverables APW Selection Guideline
Provides guidance to maintenance personnel for selection of new APW equipment for maximum leverage of the technology in the specific cleaning applications
Operational Guidelines
Developed for field tested equipment
Final Technical Report
Summarizes field trial results
6. Baseline Comparison Equipment Manufacturers
Better Engineering
25 Models
80%
MART
2 Models
Wheel & Tire Shop
Others Classes of Equipment
Small
Intermediate
Large
7. Small Class Tabletop
Usually costs under $5K
Can clean multiple small parts at one time
Most widely used: Impulse model by Better Engineering
8. Intermediate Class 2’ X 3’ Parts
$3K-15K
Most widely used in Air Force maintenance shops
9. Large Class Top loaders used when space is premium
Can cost over $60K
Mainly used in Wheel & Tire Shops
10. Screening Criteria Stainless Steel
Unique qualities (Not a clone)
Meets shop specific requirements
User friendly
Easy clean out
Less maintenance
11. Field Test Locations APWs
Small
Intermediate
Large
Bath Treatment Systems
Filtration
Evaporation Eglin 33rd FW
Propulsion Shop
Armament Shop
Wheel & Tire Shop
Barksdale AFB
2nd Wheel & Tire Shop
917th Jet Engine Shop
12. 33rd FW Propulsion Shop Small augmentor parts (F100 engine)
T.O.s
2-1-111
2J-F-100-36-10
3 authorized cleaning processes
Aqueous cleaning (substitute for solvent)
Daraclean 235XL
Large BE Top Loader
180 F water
Damaged small parts
Bucket of room temperature water
Whole afternoon
13. 33rd FW Armament Shop 2 different sized BE front loaders
Difficult to clean out (1 person, 2-3 hrs)
Large amounts of maintenance downtime
No fresh water rinse (T.O. 11W1-7-14-2) Soap
Natural Orange w/o d-limonene (MIL-C-29602 Type II [Powder])
Multiple wash cycles
Replacement of sock filter every 2 weeks
14. 33rd FW Wheel & Tire Shop Large BE Top Loader (No longer operational)
All new shop personnel
Hand cleaning w/ general aircraft cleaning soap
Most difficult cleaning task
Baseline: Seymour Johnson AFB, NC
15. 2nd Wheel & Tire Shop B-52 Wheel rims
Bath hazardous w/ significant amount of cadmium
1732 pounds annually
MART Tornado 40 w/ Daraclean 235
16. 917th Jet Engine Shop Engine depot for A-10 engines
2412 pounds annually (6 55-gallon drums)
3 different APWs w/ different cleaning solutions
17. Field Test Results
18. 33rd FW Propulsion Shop JR-1 APW
Compact size (Small footprint)
Nozzles close to parts
Can be moved about shop
Blue Gold Spray Wash identified as authorized cleaner
No way to tell when machine reaches desired temperature
19. 33rd FW Propulsion Shop
20. 33rd FW Armament Shop EMC 100E-SS APW
KISS Principle
Perforated filter screens
Hollow rectangular bars w/ drilled out holes
Basket rotated from top
Slanted tank bottom
Internal weir oil skimmer
Insulated
Switch to MIL-C-29602 Type I (Liquid) Soap
21. 33rd FW Armament Shop Cleaning
22. 33rd FW Armament Shop Maintenance
23. 33rd FW Armament Shop CLEANING EFFICIENCY: 57.2% IMPROVEMENT
357 WASH CYCLES
MANHOUR SAVINGS: 143 HOURS
PROCESS TIME SAVINGS: 428 TO 101 HOURS
MAINTENANCE SAVINGS: 340 TO 4 HOURS
24. 33rd FW Wheel & Tire Shop Harry Major Machine Swash 500
Limited Floor Space
Guillotine Door
Hinged access doors
No hard plumbing
Touch screen control panel
Water level controls
Viewing window
Axial drying fan
Insulation
Easy access bath cleanout door
Belt skimmer
Pull out parts tray
Flow through brush
Racks and fixturing
25. 33rd FW Wheel & Tire Shop
26. 33rd FW Wheel & Tire Shop
27. 33rd FW Wheel & Tire Shop
28. 33rd FW Wheel & Tire Shop
29. Seymour Johnson AFB, NC Wheel & Tire Shop
30. 33rd Wheel & Tire Shop (Main Wheels)
31. 33rd Wheel and Tire Shop (Nose Wheels)
32. 33rd FW Wheel & Tire Shop CLEANING EFFICIENCY: 46.2% IMPROVEMENT
895 MAINS
MANHOURS: 127 TO 45 HOURS
312 MAINS
MANHOURS: 21 TO 10 HOURS
33. 2nd Wheel & Tire Shop
34. 2nd Wheel & Tire Shop
35. 2nd Wheel & Tire Shop
36. 917th Jet Engine Shop
37. Summary 400% increase in life cycle
50% reduction in life cycle costs
Maintenance reduced 60%
Cleaning efficiency improved 57%
Manhours reduced 66%
Process time reduced 36%
Water Eater reduced waste by 90%
EQ-1 allowed recycling of cleaning materials
38. Aqueous Parts Washer Performance Improvement-Phase II Pollution Prevention (P2) Program
39. Better Engineering APWs • Vast majority currently fielded by the Air Force
• 25 different models
• Made from mild carbon steel
• Makes up approximately 80% of fielded systems
40. APW Baseline Requirements Deteriorated APW used in Air Force maintenance shop
To assess requirements in rehabilitating a rundown washer
Better Engineering Models
Some of the most widely used in the Air Force
Serious disrepair – extensive rusting and missing parts
41. Initial Problems with APW Test Bed Reservoir drained of liquid but not cleaned of solid waste
Sludge and other material blocked nozzles
Significant buildup of sludge – oil, grease, rust and other unidentified residue
Seriously damaged piping to filter housing
Non-reusable metal particulate filter
42. Pre-Modification
43. Pre-Modification
44. Post-Modification
45. Post-Modification
46. Rust Removers and Inhibitors Problem
Aerated cleaning solution + elevated temperatures = rapid corrosion of mild carbon steel
High pH(13 –14) minimized corrosion
High pH not compatible with other materials
Solution
Rust inhibitors from APW manufacturers / other sources
Added to rinse water – prevent flash rusting
Can be added to cleaning solution
Effective in reducing rusting of parts
May be effective in reducing rust on interior surfaces of APWs
48. Rust Removal Evapo-Rust cabinet cleaner
49. Rust Removal Evaluation
50. Modification Alternatives APW Possesses Several Subsystems
1. The Machine’s Ability to Clean
Pump Assembly
Spray Nozzles
Heaters
Cleaning Solution
2. Maintaining Bath Quality
Particulate Filtration
Oil Removal System
Rust Inhibitors 3. Meeting Shop Specific Technical Requirements
Fresh Water Rinse
Drying System
4. Addressing Phase I Concerns
Secondary Cleaning
Bath Cleanout
Insulation
51. Cleaning Options Fresh Water Rinse
Technical orders requiring fresh water rinse
Use to remove any remaining soap from parts
May also remove any rust inhibitors from parts
Can be added to current systems
52. Nozzle Optimization Nozzle calculations to determine proper nozzle angles
Cleaning efficiency determined on a weight difference method
53. Nozzle Optimization
54. Nozzle Optimization Results (Painted Panels)
