REG NASA-LLIS-0804--2000 Lessons Learned Contamination Budgeting for Space Optical Systems.pdf

1、Best Practices Entry: Best Practice Info:a71 Committee Approval Date: 2000-04-17a71 Center Point of Contact: MSFCa71 Submitted by: Wil HarkinsSubject: Contamination Budgeting for Space Optical Systems Practice: Use preplanned contamination budgeting for each manufacturing/assembly, testing, shipping

2、, launch, and flight operation and meticulously test optical systems using witness samples throughout the process to track actual contamination against total and incremental allocations.Programs that Certify Usage: This practice has been used on Apollo Telescope Mount (ATM), High Energy Astronomy Ob

3、servatory (HEAO), Hubble Space Telescope (HST), Advanced X-Ray Astrophysics Facility (AXAF).Center to Contact for Information: MSFCImplementation Method: This Lesson Learned is based on Reliability Practice No. PD-ED-1241; from NASA Technical Memorandum 4322A, NASA Reliability Preferred Practices fo

4、r Design and Test.Benefit:Budgeting of a specific amount of the established allowable contamination to the major elements and operations during fabrication, assembly, testing, transportation launch support, and launch and on orbit operations of space optical systems will preclude jeopardizing the sc

5、ientific objectives of the mission. Budgeting of contamination to major elements will ensure that the cleanliness of the optics Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-and instruments will remain within designated optical requirements for ope

6、rations in space. Reliability of the scientific objectives are increased by limiting the contamination allowed to the optical systems during each operation, which ensures that contamination during orbital operations is within specification.Implementation Method:1. IntroductionContamination budgeting

7、 allocations for optical systems should be developed by the chief scientist, systems engineer, and the contamination control engineer using information generated from requirements documents, interface control documents, science working groups, contamination control working groups, contamination cont

8、rol review panels, contamination effects analyses, contamination testing programs, and direct customer involvement. The experience gained from other programs to budget and control contamination is also an input to the determination of a contamination budget. Another factor that should be considered

9、is the cost of controlling contamination versus the scientific payback. The effective control of contamination may require: (1) investments in clean room facilities, (2) training of personnel in clean room operations, (3) monitoring of clean room activities and air quality, (4) acceptance of ineffic

10、iencies in working conditions caused by special clothing, restricted space and contamination avoidance provisions, and (5) potential performance tradeoff (i.e., use of cleanable or conductive coatings, modified thermal controls, and use of windows).2. Budgeting for ContaminationThe two principal typ

11、es of contamination sources for optical systems are particulate contamination and molecular contamination. Particulate contamination can consist of airborne particles, insulation shreds, clothing fibers, other human induced substances, and trapped particles in interstitial spaces, such as joints and

12、 crevices. When these particles settle on the optical surfaces, they cause degradation by obscuration and light scattering. To avoid jeopardizing the scientific objectives of the HST, the maximum percentage area coverage due to particulate contamination for the primary and secondary mirror was set a

13、t 5 percent.Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-refer to D descriptionD Figure 1. HST Particle Contamination Budget Allocation Molecular contamination results from depositing outgassed products on optical surfaces, which may cause perform

14、ance degradation at most wavelengths by absorbing the wave energy and/or modify polarization characteristics. Examples of molecular contaminants are lubricants, exposed organics, and volatile condensible materials. The allowed (per scientific objectives of HST) degradation due to molecular contamina

15、tion dictates that the reflectance at 1216 Angstroms shall not decrease by more than 10 percent between the time of coating and five years in orbit. The operations that have the greatest potential for contamination have been allocated the larger budgets.3. ReallocationThe requirement that limits the

16、 primary and secondary mirror area coverage total contamination budget cannot be changed. However, changes may occur in the schedule where the operational budget may have to be re-allocated. For example, in the particulate contamination budget for the HST, the original allocation of 1.35 percent ass

17、igned to pre-acoustic fallout and the chimney effect Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-and the 1.35 percent assigned to the acoustic testing were changed to 1.30 percent. The 0.6 percent assigned to the fallout and chimney effect after

18、acoustic testing was changed to 0.5 percent. The total of 0.2 percent obtained from these operations was assigned to the unplanned rework and storage operation.refer to D descriptionD Figure 2. HST Molecular Contamination Budget Allocation Technical Rationale:For an optical system to achieve its des

19、ired goal of returning adequate scientific results, contamination of the optical system must be kept to a minimum. Establishing a contamination budget and controlling the contaminates within this budget ensures that the optical system will produce satisfactory scientific results.References:1. LMSC 4

20、176437D: “Hubble Space Telescope Contamination Control Plan,“ Lockheed Missiles and Space Co., Inc., (LMSC) January 30, 1987.2. LMSC 4176594A: “Contamination Degradation Budget Allocation,“ ST/SE-26 Appendix A, Lockheed Missiles and Space Co., Inc., June 4, 1984.3. LMSC 4176595C: “HST Environment De

21、finition and Traceability,“ ST/SE-26 Appendix B, Lockheed Missiles and Space Co., Inc., July 13, 1990.4. LMSC 4176596A: “HST Contamination Control Training,“ ST/SE-26 Appendix C, Lockheed Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-Missiles and S

22、pace Co., Inc., November 15, 1984.5. LMSC 4176597A: “ST Contamination Control Violation Reports,“ ST/SE-26 Appendix D, Lockheed Missiles and Space Co., Inc., October 30, 1984.6. LMSC 4176598A: “ST Thermal Vacuum Bake Out,“ ST/SE-26 Appendix E, Lockheed Missiles and Space Co., Inc., March 31, 1988.7.

23、 LMSC 4176599B: “HST Cleanliness Status,“ ST/SE-26 Appendix F, Lockheed Missiles and Space Co., Inc., August 30, 1990.8. LMSC/F157834: “Contamination Control Implementation Plan for HST Rework and Storage,“ Lockheed Missiles and Space Co., Inc., November 1, 1986.9. LMSC/D975220D: “Hubble Space Teles

24、cope, Maintenance and Refurbishment Contamination Control Master Plan,“ Lockheed Missiles and Space Co., Inc., June 30, 1988.10. NASA SP-5076: “Contamination Control Handbook,“ National Aeronautics and Space Administration, 1969.Impact of Non-Practice: Nonpractice could result in unacceptable degrad

25、ation of the optical system with unacceptable scientific results and considerable loss of resources.Related Practices: N/AAdditional Info: Approval Info: a71 Approval Date: 2000-04-17a71 Approval Name: Eric Raynora71 Approval Organization: QSa71 Approval Phone Number: 202-358-4738Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-