AGENCY:

Federal Aviation Administration, DOT.

ACTION:

Final rule.

SUMMARY:

This amendment supersedes an existing airworthiness directive (AD) that applies to Model HH-1K, TH-1F, TH-1L, UH-1A, UH-1B, UH-1E, UH-1F, UH-1H, UH-1L, UH-1P, and Southwest Florida Aviation Model SW204, SW204HP, SW205, and SW205A-1 helicopters, manufactured by Bell Helicopter Textron, Inc. (BHTI) for the Armed Forces of the United States. That AD currently requires establishing retirement lives for certain main rotor masts, creating a component history card or equivalent record, and identifying and replacing any unairworthy masts. That AD also contains certain requirements regarding the hub spring, conducting inspections based on the retirement index number (RIN), and sending information to the FAA. This AD contains the same requirements but would establish a retirement life for the main rotor trunnion (trunnion) based on monitoring the number of torque events and flight hours rather than flight hours only as currently required. This AD also adds a note clarifying that the mast serial number (S/N) is defined by 5 or fewer digits plus various prefixes. This amendment is prompted by the determination that monitoring the number of torque events and flight hours for the trunnion is more accurate than by monitoring flight hours only to establish a retirement life. The actions specified by this AD are intended to prevent failure of a mast or trunnion, separation of the main rotor system, and subsequent loss of control of the helicopter.

EFFECTIVE DATE:

March 8, 2002.

FOR FURTHER INFORMATION CONTACT:

Michael Kohner, Aviation Safety Engineer, FAA, Rotorcraft Directorate, Rotorcraft Certification Office, Fort Start Printed Page 4879Worth, Texas 76193-0170, telephone (817) 222-5447, fax (817) 222-5783.

SUPPLEMENTARY INFORMATION:

A proposal to amend 14 CFR part 39 by superseding AD 2000-22-51, Amendment 39-12034 (65 FR 77263, December 11, 2000), which applies to Model HH-1K, TH-1F, TH-1L, UH-1A, UH-1B, UH-1E, UH-1F, UH-1H, UH-1L, UH-1P, and Southwest Florida Aviation Model SW204, SW204HP, SW205, and SW205A-1 helicopters, manufactured by BHTI for the Armed Forces of the United States, was published in the Federal Register on September 21, 2001 (66 FR 48631). In addition to retaining several of the requirements of AD 2000-22-51, that action proposed establishing a retirement life for the trunnions based on monitoring the number of torque events and flight hours. Also proposed was adding a note clarifying that the mast S/N is defined by 5 or fewer digits plus various prefixes.

Interested persons have been afforded an opportunity to participate in the making of this amendment. Due consideration has been given to the comment received.

The one commenter states that when the details in paragraphs (a)(2)(i) and (b)(2)(i) of the AD are unavailable for a particular component but the total time-in-service (TIS) is known, he suggests that the worst possible combination for RIN and TIS count should be applied and recorded and the FAA should not require that the component be removed from service. The FAA does not concur. Even assuming the worst case scenario proposed by the commenter would not necessarily provide an appropriate safety margin. The helicopter model installation history and the hours TIS are required to ensure that the mast or trunnion has not been installed on any ineligible helicopter. Masts purchased from the U.S. military should have the part records with the helicopter model installation history and hours TIS.

The FAA has determined that air safety and the public interest require the adoption of the rule as proposed except that an editorial change has been made to the reporting requirements information, paragraph (9) of the AD. The FAA has determined that this change neither increases the economic burden on any operator nor increases the scope of the AD.

The FAA estimates that this AD will affect 75 helicopters of U.S. registry. The FAA also estimates that it will take 10 work hours to replace the trunnion, 2 work hours per helicopter to create a new component history card or equivalent record for the trunnions and that the average labor rate is $60 per work hour. Required trunnions will cost approximately $5,300 per helicopter. Based on these figures, the total cost impact of this AD on U.S. operators is estimated to be $451,500.

The regulations adopted herein will not have a substantial direct effect on the States, on the relationship between the national Government and the States, or on the distribution of power and responsibilities among the various levels of government. Therefore, it is determined that this final rule does not have federalism implications under Executive Order 13132.

For the reasons discussed above, I certify that this action (1) is not a “significant regulatory action” under Executive Order 12866; (2) is not a “significant rule” under DOT Regulatory Policies and Procedures (44 FR 11034, February 26, 1979); and (3) will not have a significant economic impact, positive or negative, on a substantial number of small entities under the criteria of the Regulatory Flexibility Act. A final evaluation has been prepared for this action and it is contained in the Rules Docket. A copy of it may be obtained from the Rules Docket at the FAA, Office of the Regional Counsel, Southwest Region, 2601 Meacham Blvd., Room 663, Fort Worth, Texas.

List of Subjects in 14 CFR Part 39

• Air transportation
• Aircraft
• Aviation safety
• Safety

Adoption of the Amendment

Accordingly, pursuant to the authority delegated to me by the Administrator, the Federal Aviation Administration amends part 39 of the Federal Aviation Regulations (14 CFR part 39) as follows:

PART 39—AIRWORTHINESS DIRECTIVES

1. The authority citation for part 39 continues to read as follows:

Authority: 49 U.S.C. 106(g), 40113, 44701.

2. Section 39.13 is amended by removing Amendment 39-12034 ( 65 FR 77263, December 11, 2000), and by adding a new airworthiness directive (AD), Amendment 39-12628, to read as follows:

2002-01-31 Arrow Falcon Exporters, Inc. (Previously Utah State University); Firefly Aviation Helicopter Services (Previously Erickson Air-crane Co.); Garlick Helicopters, Inc.; Hawkins and Powers Aviation, Inc.; International Helicopters, Inc.; Robinson Air Crane, Inc.; Smith Helicopters; Southern Helicopter, Inc.; Southwest Florida Aviation; Tamarack Helicopters, Inc. (Previously Ranger Helicopter Services, Inc.); U.S. Helicopter, Inc.; Western International Aviation, Inc., and Williams Helicopter Corporation (Previously Scott Paper Co.):

Amendment 39-12628. Docket No. 2001-SW-14-AD. Supersedes AD 2000-22-51, Amendment 39-12034, Docket No. 2000-SW-42-AD.

Applicability: Model HH-1K, TH-1F, TH-1L, UH-1A, UH-1B, UH-1E, UH-1F, UH-1H, UH-1L, and UH-1P; and Southwest Florida Aviation SW204, SW204HP, SW205, and SW205A-1 helicopters, manufactured by Bell Helicopter Textron Inc. (BHTI) for the Armed Forces of the United States, with main rotor mast (mast), part number (P/N) 204-011-450-007, -105, or -109, or main rotor trunnion (trunnion), P/N 204-011-105-001, installed, certificated in any category.

Note 1:

This AD applies to each helicopter identified in the preceding applicability provision, regardless of whether it has been otherwise modified, altered, or repaired in the area subject to the requirements of this AD. For helicopters that have been modified, altered, or repaired so that the performance of the requirements of this AD is affected, the owner/operator must request approval for an alternative method of compliance in accordance with paragraph (c) of this AD. The request should include an assessment of the effect of the modification, alteration, or repair on the unsafe condition addressed by this AD; and if the unsafe condition has not been eliminated, the request should include specific proposed actions to address it.

Compliance: Required as indicated, unless accomplished previously.

Note 2:

This AD requires using new factors to recalculate the FACTORED flight hours and the accumulated Retirement Index Number (RIN) for masts installed on certain helicopter models. This AD also expands the serial number (S/N) applicability for the one-time special inspection of the mast.

To prevent failure of a mast or trunnion, separation of the main rotor system, and subsequent loss of control of the helicopter, accomplish the following:

(a) For the mast, P/N 204-011-450-007, -105, or -109:

Note 3:

The next higher assembly level for the affected P/N's are the 204-040-366 mast assemblies. Check the helicopter records for the appropriate P/N and assembly level.

(1) Within 10 hours time-in-service (TIS), create a component history card or equivalent record for the mast.

(2) Within 10 hours TIS, determine and record the accumulated RIN and revised hours TIS for the mast as follows:

(i) Review the helicopter maintenance records for the mast. If you do not know the helicopter model installation history or hours TIS of the mast, remove the mast from service, identify the mast as unairworthy, and replace it with an airworthy mast before further flight. Start Printed Page 4880

(ii) Calculate the accumulated RIN and the revised hours TIS for the mast in accordance with the instructions in Appendix 1 to this AD. For those hours TIS the mast has been installed on any other helicopter, calculate the RIN for that trunnion in accordance with the requirements for those helicopters.

(iii) Record the accumulated RIN and revised hours TIS for the mast on the component history card or equivalent record. Use the revised hours TIS as the new hours TIS for the mast.

(3) Before further flight after accomplishing the requirements of paragraph (a)(2) of this AD, remove from service any mast that has accumulated 265,000 or more RIN or 15,000 or more revised hours TIS and identify the mast as unairworthy. Replace the mast with an airworthy mast.

(4) Within 25 hours TIS, remove any hub spring installed on any affected helicopter.

Note 4:

U.S. Army Modification Work Order (MWO) 55-1520-242-50-1 pertains to the removal of the hub spring and replacement of any required parts. U.S. Army Safety of Flight Message UH-1-00-10 dated July 19, 2000, also pertains to the subject of this AD.

(5) Determine whether a mast with a S/N less than and including 52720, 61433 through 61444, or 61457 through 61465 (regardless of prefix), has ever been installed on a helicopter while operated with a hub spring.

Note 5:

The mast S/N consists of 5 or less numerical digits and may be preceded by one of the following prefixes: NFS, N9, H, AC9, CP, FA, H9, N19, RH9, or NC. There may be other prefixes in addition to those listed. The prefix and S/N may or may not be separated by a dash.

(i) If a mast has never been installed on a helicopter while operated with a hub spring, before reaching 100,000 RIN, inspect the upper and lower snap ring grooves in the damper clamp splined area for:

(A) A minimum radius of 0.020 inch around the entire circumference (see Figures 1 and 2), using a 100x or higher magnification. If any snap ring groove radius is less than 0.020 inch, identify the mast as unairworthy and replace it with an airworthy mast before exceeding 100,000 RIN.

(B) A burr (see Figures 1 through 3), using a 200x or higher magnification. If a burr is found in any snap ring groove/spline intersection, identify the mast as unairworthy and replace it with an airworthy mast before exceeding 170,000 RIN.

(ii) If a mast has ever been installed on a helicopter while operated with a hub spring or if you do not know whether a hub spring has ever been installed, before reaching 100,000 RIN or 400 unfactored flight hours, whichever occurs first, inspect the upper and lower snap ring grooves in the damper clamp splined area for:

(A) A minimum radius of 0.020 inch around the entire circumference (see Figures 1 and 2), using a 100x or higher magnification. If any snap ring groove radius is less than 0.020 inch, identify the mast as unairworthy and replace it with an airworthy mast before further flight.

(B) A burr (see Figures 1 through 3), using a 200x or higher magnification. If a burr is found in any snap ring groove/spline intersection, identify the mast as unairworthy and replace it with an airworthy mast before further flight.

(6) After accomplishing the requirements of paragraph (a)(2) of this AD, continue to calculate the accumulated RIN for the mast by multiplying all takeoff and external load lifts by the RIN factors defined in columns (D) and (G) of Table 1 of Appendix 1 of this AD.

(7) After accomplishing the requirements of paragraph (a)(2) of this AD, continue to count the hours TIS for the mast. Any hours TIS for the mast while installed on a helicopter operated with a hub spring or those hours during which you do not know whether a hub spring was installed must be factored in accordance with the instructions in Appendix 1 of this AD.

(8) This AD establishes a retirement life of 265,000 accumulated RIN or 15,000 hours TIS, whichever occurs first, for mast, P/N 204-011-450-007, -105, and -109.

(9) Within 10 days after completing the inspections required by paragraph (a)(5) of this AD, send the information contained on the AD compliance inspection report sample format contained in Appendix 2 to the Manager, Rotorcraft Certification Office, Federal Aviation Administration, Fort Worth, Texas, 76193-0170, USA. Information collection requirements contained in this AD have been approved by the Office of Management and Budget (OMB) under the provisions of the Paperwork Reduction Act of 1980 (44 U.S.C. 3501 et seq.) and have been assigned OMB Control Number 2120-0056.

(b) For the trunnion, P/N 204-011-105-001:

(1) Within 10 hours TIS, create a component history card or equivalent record for the trunnion.

(2) Within 10 hours TIS, determine and record the accumulated RIN and revised hours TIS for the trunnion as follows:

(i) Review the helicopter maintenance records for the trunnion. If the helicopter model installation history or hours TIS of the trunnion are unknown, remove the trunnion from service, identify the trunnion as unairworthy, and replace it with an airworthy trunnion before further flight.

(ii) Calculate the accumulated RIN and the revised hours TIS in accordance with the instructions in Appendix 3 to this AD. For those hours TIS the trunnion has been installed on any other helicopter, calculate the RIN for that trunnion in accordance with the requirements for those helicopters.

(iii) Record the accumulated RIN and revised hours TIS for the trunnion on the component history card or equivalent record. Use the revised hours TIS as the new hours TIS for the trunnion.

(3) Before further flight after accomplishing the requirements of paragraph (b)(2) of this AD, remove from service any trunnion that has accumulated 300,000 or more RIN or 15,000 or more revised hours TIS and identify the trunnion as unairworthy. Replace the trunnion with an airworthy trunnion.

(4) After accomplishing the requirements of paragraph (b)(2) of this AD, continue to calculate the accumulated RIN for the trunnion by multiplying all takeoff and external load lifts by the RIN factors defined in columns (D) and (G) of Table 1 of Appendix 3 to this AD.

(5) After accomplishing the requirements of paragraph (b)(2) of this AD, continue to count the hours TIS for the trunnion.

(6) This AD establishes a retirement life of 300,000 accumulated RIN or 15,000 hours TIS, whichever occurs first, for the trunnion, P/N 204-011-105-001.

(c) An alternative method of compliance or adjustment of the compliance time that provides an acceptable level of safety may be used if approved by the Manager, Rotorcraft Certification Office, FAA. Operators shall submit their requests through an FAA Principal Maintenance Inspector, who may concur or comment and then send it to the Manager, Rotorcraft Certification Office.

Note 6:

Information concerning the existence of approved alternative methods of compliance with this AD, if any, may be obtained from the Manager, Rotorcraft Certification Office.

(d) Special flight permits may be issued in accordance with 14 CFR 21.197 and 21.199 to operate the helicopter to a location where the requirements of this AD can be accomplished.

Appendix 1—Instructions for Calculating the RIN and Revised Hours TIS

Definitions for the RIN:

The overall fatigue life of a main rotor mast is a function of the number of cycles of torque, lift, and bending loads applied to it during the various modes of operation. The mast experiences both high cycle fatigue and low cycle fatigue during operation.

The high cycle fatigue life of the mast is a function of high frequency but relatively low level cyclic loads, which are primarily Start Printed Page 4884induced by rotor rpm. The high cycle fatigue life limit for the mast is defined in terms of hours TIS because rotor rpm is basically a constant value.

The low cycle fatigue life of the mast is a function of the number of less frequent but relatively high level cyclic loads experienced primarily during takeoffs and external load lifts. The low cycle fatigue life limit for the mast is expressed in terms of the accumulated RIN.

A load cycle is a power cycle caused by a repeating or fluctuating load that alternates from a starting power value, goes to a higher power value, and returns to the starting power value.

The accumulated RIN is defined as the total number of load cycles multiplied by a RIN factor to account for the difference in torque levels applied to the same mast (since manufactured) when installed in different helicopter models. The level of torque applied to the mast is directly proportional to the transmission output horsepower.

The unfactored hours TIS is the time from the moment a helicopter leaves the surface of the earth until it touches it at the next point of landing with no factors applied.

The FACTORED flight hours is the unfactored hours TIS multiplied by a frequency of event hour factor based on the torque (horsepower) of the helicopter model in which it was installed and the usage of the helicopter.

The revised hours TIS is the new hours TIS for the mast as determined by following the instructions in this appendix.

An external load lift is defined as a lift where the load is carried, or extends, outside of the aircraft fuselage.

Calculation of RIN and Revised Hours TIS:

There are two methods for calculating the accumulated RIN and the revised hours TIS, depending on the available service history information for the mast. In some cases, one method will be used for a portion of the mast service history, and the other method will be used for another portion of the mast service history. Both methods require knowledge of all the helicopter models in which the mast was installed.

Calculation of RIN and Revised Hours TIS when the Exact Number of Takeoffs and External Load Lifts is Known (Reference Tables 1 and 3):

Table 1 of Appendix 1 is the worksheet for calculating the accumulated mast RIN when the exact number of takeoffs and external load lifts is known. Table 3 of Appendix 1 is the worksheet that has the frequency of event hour factors to calculate the FACTORED flight hours for the unfactored hours TIS for the mast while installed on a helicopter operated with a hub spring or the hub spring installation history is unknown.

The RIN factor for each external load lift is twice that specified for each takeoff because two torque events are experienced during a typical external load lift.

Using Table 1, calculate accumulated RIN as follows:

1. Enter the total number of takeoffs for the particular mast model/helicopter model combination in column (C).

2. Multiply the value entered in column (C) by the RIN factor listed in column (D), and enter the result in column (E). This is the total accumulated RIN due to takeoffs.

3. Enter the total number of external load lifts for the particular mast model/helicopter model combination in column (F).

4. Multiply the value entered in column (F) by the RIN factor listed in column (G), and enter the result in column (H). This is the accumulated RIN due to external load lifts.

5. Add the values from column (E) and column (H) and enter the result in column (I). This is the total accumulated RIN to-date for the mast for the particular mast model/helicopter model combination.

6. Add the accumulated RIN subtotals for the various mast model/helicopter combinations in column (I) and enter the result in the space provided. This is the total accumulated RIN for the mast.

Using Table 3, calculate the revised hours TIS as follows:

7. Determine the unfactored hours TIS for the mast while installed on a helicopter operated with a hub spring or the number of hours TIS for which you do not know whether a hub spring was installed for each of the particular mast model/helicopter model combinations.

8. Determine the frequency of events per hour for each of the particular mast model/helicopter model combinations dividing the combined number of takeoffs and external load lifts by the corresponding unfactored hours TIS.

9. Multiply the value for unfactored hours TIS for each of the particular mast model/helicopter model combinations by the appropriate value in column (E) of Table 3 for the frequency of event hour factor. These are the total FACTORED flight hours for the particular mast model/helicopter model combinations.

10. Add the FACTORED flight hour subtotals for each of the particular mast model/helicopter model combinations. This is the total FACTORED flight hours for the mast while installed on a helicopter operated with a hub spring or when you do not know whether a hub spring was installed.

11. Determine the unfactored hours TIS for the mast while installed on a helicopter operated without a hub spring.

12. Add to the total FACTORED flight hours for the mast while installed on a helicopter operated with a hub spring or those hours during which you do not know whether a hub spring was installed to the unfactored hours TIS as determined in step 11. This is the total revised hours TIS for the mast when the exact number of takeoffs and external load lifts is known.

Calculation of RIN and Revised Hours TIS when Exact Number of Takeoffs and External Load Lifts is Unknown (Reference Tables 2, 3, and 4):

Tables 2, 3, and 4 of Appendix 1 are the worksheets for calculating the FACTORED flight hours and accumulated mast RIN when the exact number of takeoffs and external load lifts is unknown.

Using Tables 2, 3, and 4, calculate the accumulated mast RIN and revised hours TIS as follows:

1. Enter the unfactored hours TIS for the particular mast model/helicopter model combination in column (C) of Tables 2 and 3.

2. Using service history for the mast, select the appropriate frequency of event hour factor from column (E) of Tables 2 and 3 based on the total combined number of takeoffs and external load lifts per hour shown in column (D).

3. Multiply the value for unfactored hours TIS entered in column (C) by the appropriate value in column (E) for the frequency of event hour factor as determined in step 2. Enter the result in column (F) of Tables 2 and 3. This is the total FACTORED flight hours for the particular mast model/helicopter model combination.

4. Enter the value for FACTORED flight hours from column (F) of Tables 2 and 3 into column (C) of Table 4.

5. Using Table 4, multiply the value for FACTORED flight hours in column (C) by the appropriate RIN conversion factor listed in column (D), by the appropriate RIN adjustment factor in column (E), and enter the result in column (F). This is the accumulated RIN to-date for the particular mast model/helicopter model combination.

6. Add the accumulated RIN subtotals for the various mast model/helicopter model combinations in column (F) of Table 4 and enter the result in the space provided. This is the total accumulated RIN for the mast.

7. Add the factored flight hour subtotals for the various mast model/helicopter model combinations as determined in steps 1 through 4. This is the total revised hours TIS for the mast when the exact number of takeoffs and external load lifts is unknown.

Sample Mast Calculation

Given the following known service history for the mast:

Mast, P/N 204-011-450-007, was first purchased as a United States military surplus part with valid historical records. The mast had accumulated 550 hours military TIS on an Army UH-1H with a hub spring installed.

The mast was first installed on a restricted category UH-1H former military helicopter for 250 hours TIS. The helicopter had a rating of 1100 takeoff horsepower (T.O. hp) at sea level standard day conditions (SLS), and the operation of the helicopter without a hub spring cannot be determined. The helicopter was used for fire fighting operations and the exact number of takeoffs and external load lifts is unknown. It is known, however, that the helicopter averaged less than 15 combined takeoffs and external load lifts per hour.

The mast was then removed and subsequently installed on a restricted category UH-1E former military helicopter (1100 T.O. hp SLS rating) without a hub spring for 450 hours TIS. It is known that the helicopter was used primarily for aerial surveying for the first 200 hours of operation. The exact number of takeoffs and external load lifts is unknown, but it is known that the helicopter averaged less than 16 takeoffs per hour, with no external load lifts. It was subsequently used for repeated heavy lift operation for the next 250 hours of operation and averaged between 25 and 31 combined Start Printed Page 4885takeoffs and external load lifts per hour during this period of time.

The mast was then removed and installed on another restricted category UH-1H former military helicopter (1100 T.O. hp SLS rating) for a total of 150 hours TIS with accurate records indicating that it experienced 100 takeoffs and 2,450 external load lifts. A hub spring was installed on the helicopter for the first 50 hours of operation with a calculated average of 19 combined takeoffs and external load lifts per hour (as determined from aircraft records for the first 50 hours of operation). The hub spring was subsequently removed for the remaining 100 hours TIS.

Calculate the FACTORED flight hours and total accumulated RIN for the mast as follows:

FACTORED Flight Hours and Accumulated RIN while installed in U.S. military Model UH-1H:

Calculate FACTORED flight hours from Table 3 as follows:

FACTORED Flight Hours

= (unfactored hours TIS) × (frequency of event hour factor)

= (column C) × (column E)

= (550) × (10)

= 5,500 hours

Then using Table 4, calculate the accumulated RIN as follows:

Accumulated RIN

= (FACTORED flight hours) × (RIN conversion factor) × (RIN adjustment factor)

= (column C) × (column D) × (column E)

= (5,500) × (20) × (1)

= 110,000 RIN

FACTORED Flight Hours and Accumulated RIN while installed in restricted category Model UH-1H:

Calculate FACTORED flight hours from Table 3 as follows:

FACTORED Flight Hours

= (unfactored hours TIS) × (frequency of event hour factor)

= (column C) × (column E)

= (250) × (14)

= 3,500 hours

Then using Table 4, calculate the accumulated RIN as follows:

Accumulated RIN

= (FACTORED flight hours) × (RIN conversion factor) × (RIN adjustment factor)

= (column C) × (column D) × (column E)

= (3,500) × (20) × (1)

= 70,000 RIN

FACTORED Flight Hours and Accumulated RIN while installed in restricted category Model UH-1E:

Calculate FACTORED flight hours from Table 2 as follows:

FACTORED Flight Hours (for first 200 hrs.)

= (unfactored hours TIS) × (frequency of event hour factor)

= (column C) × (column E)

= (200) × (5)

= 1,000 hours

FACTORED Flight Hours (for next 250 hrs.)

= (unfactored hours TIS) × (frequency of event hour factor)

= (column C) × (column E)

= (250) × (10)

= 2,500 hours

Then using Table 4, calculate the accumulated RIN as follows:

Accumulated RIN

= (FACTORED flight hours) × (RIN conversion factor) × (RIN adjustment factor)

= (column C) × (column D) × (column E)

= (1,000) × (20) × (1) + (2,500) × (20) × (1)

= 20,000 + 50,000

= 70,000 RIN

FACTORED Flight Hours and Accumulated RIN while installed in another restricted category Model UH-1H:

Calculate the accumulated RIN from Table 1 and the given number of takeoffs and external load lifts as follows:

Accumulated RIN

= (number of takeoffs × RIN factor per takeoff) + (number of external load lifts × RIN factor per external load lifts.

= (column C) × (column D) + (column F) × (column G)

= (100) × (3) + (2,450) × (6)

= 15,000 RIN

Calculate the FACTORED flight hours for the mast while installed on a helicopter operated with a hub spring or when you do not know whether a hub spring was installed using the frequency of event hour factors from Table 3 as follows:

FACTORED Flight Hours (w/ hub spring)

= (unfactored hours TIS) × (frequency of event hour factor)

= (column C) × (column E)

= (50) × (16)

= 800 hours

Unfactored Hours TIS (w/o hub spring)

= (unfactored hours TIS)

= 100 hours

Note that the FACTORED flight hours are not used in the accumulated RIN calculations when the number of takeoffs and external load lifts is known.

Calculate the Total Accumulated RIN and Revised Hours TIS as follows:

The total accumulated RIN to-date for the mast is the sum of the subtotals from Tables 1 and 4.

Total Accumulated RIN

= 110,000 + 70,000 + 70,000 + 15,000

= 265,000

The total FACTORED flight hours for the mast is the sum of the subtotals from Tables 2 and 3 and the total FACTORED flight hours as determined in the preceding step 12 when the exact number of takeoff and external load lifts is known.

Total FACTORED Flight Hours

= 5,500 + 3,500 + 1,000 + 2,500 + 800

= 13,300 hours

The revised hours TIS to-date for the mast is the sum of the total FACTORED flight hours and the additional unfactored hours TIS for the mast while installed on a helicopter operated without a hub spring and the exact number of takeoffs and external load lifts is known.

Revised Hours TIS

= 5,500 + 3,500 + 1,000 + 2,500 + 800 + 100

= 13,300 + 100

= 13,400 hours

Both the total accumulated RIN and the revised hours TIS need to be determined and checked for exceeding the allowable life limits for the mast. Also, note that the recalculated total accumulated RIN for this sample mast would be 265,000 RIN. Therefore, this mast would be removed from service.

The values for the sample problem are shown in Tables 1-4 for illustration purposes only. The FACTORED flight hours TIS shown in the brackets in Table 3 are calculated for the mast while installed on a helicopter operated with a hub spring or when you do not know whether a hub spring was installed and the exact number of takeoffs and external load lifts is known. These FACTORED flight hours are not used in the accumulated RIN calculations.

Appendix 2— AD Compliance Inspection Report (Sample Format) P/N 204-011-450-007/-105/-109 Main Rotor Mast

Provide the following information and mail or fax it to: Manager, Rotorcraft Certification Office, Federal Aviation Administration, Fort Worth, Texas, 76193-0170, USA, Fax: 817-222-5783

Aircraft Registration No:

Helicopter Model:

Helicopter S/N:

Mast P/N:

Mast S/N:

Mast RIN:

Mast Total TIS:

Inspection Results

Were any radii during inspection of this mast determined to be less than 0.020 inch? If yes, what was the dimension measured?

Was a burr found in the inspected snap ring grooves?

Were cracks noted during the inspection?

Who performed this inspection?

Provide any other comments?

Appendix 3—Instructions for Calculating Trunnion RIN and Revised Hours TIS

Definitions for the RIN:

The overall fatigue life of a main rotor trunnion is a function of the number of cycles of torque, lift, and bending loads applied to it during the various modes of operation. The trunnion experiences both high cycle fatigue and low cycle fatigue during operation.

The high cycle fatigue life of the trunnion is a function of high frequency but relatively low level cyclic loads, which are primarily induced by rotor rpm. The high cycle fatigue life limit for the trunnion is defined in terms of hours TIS because rotor rpm is basically a constant value.

The low cycle fatigue life of the trunnion is a function of the number of less frequent but relatively high level cyclic loads experienced primarily during takeoffs and external load lifts. The low cycle fatigue life limit for the trunnion is expressed in terms of the accumulated RIN.

A load cycle is a power cycle caused by a repeating or fluctuating load that alternates from a starting power value, goes to a higher power value, and returns to the starting power value.

The accumulated RIN is defined as the total number of load cycles multiplied by a RIN factor to account for the difference in torque levels applied to the same trunnion (since manufactured) when installed in different helicopter models. The level of torque applied to the trunnion is directly proportional to the transmission output horsepower.

The unfactored hours TIS is the time from the moment a helicopter leaves the surface of the earth until it touches it at the next point of landing with no factors applied.

The FACTORED flight hours is the unfactored hours TIS multiplied by a frequency of event hour factor based on the torque (horsepower) of the helicopter model in which it was installed and the usage of the helicopter.

The revised hours TIS is the new hours TIS for the trunnion as determined by following the instructions in this appendix.

An external load lift is defined as a lift where the load is carried, or extends, outside of the aircraft fuselage.

Calculation of RIN and Revised Hours TIS:

There are two methods for calculating the accumulated RIN and the revised hours TIS, depending on the available service history information for the trunnion. In some cases, one method will be used for a portion of the trunnion service history, and the other method will be used for another portion of the trunnion service history. Both methods require knowledge of all the helicopter models in which the trunnion was installed.

Calculation of RIN and Revised Hours TIS when the Exact Number of Takeoffs and External Load Lifts is Known (Reference Table 1):

Table 1 of Appendix 3 is the worksheet for calculating the accumulated trunnion RIN when the exact number of takeoffs and external load lifts is known.

The RIN factor for each external load lift is twice that specified for each takeoff because two torque events are experienced during a typical external load lift.

Using Table 1, calculate the accumulated RIN as follows:

1. Enter the total number of takeoffs for the particular trunnion model/helicopter model combination in column (C).

2. Multiply the value entered in column (C) by the RIN factor listed in column (D), and enter the result in column (E). This is the total accumulated RIN due to takeoffs.

3. Enter the total number of external load lifts for the particular trunnion model/helicopter model combination in column (F).

4. Multiply the value entered in column (F) by the RIN factor listed in column (G), and enter the result in column (H). This is the accumulated RIN due to external load lifts.

5. Add the values from column (E) and column (H) and enter the result in column (I). This is the total accumulated RIN to-date for the trunnion for the particular trunnion model/helicopter model combination.

6. Add the accumulated RIN subtotals for the various trunnion model/helicopter combinations in column (I) and enter the result in the space provided. This is the total accumulated RIN for the trunnion.

Calculation of RIN and Revised Hours TIS when Exact Number of Takeoffs and External Load Lifts is Unknown (Reference Tables 2 and 3):

Tables 2 and 3 of Appendix 3 are the worksheets for calculating the FACTORED flight hours and accumulated trunnion RIN when the exact number of takeoffs and external load lifts is unknown.

Using Tables 2 and 3, calculate the accumulated trunnion RIN and revised hours TIS as follows:

1. Enter the unfactored hours TIS for the particular trunnion model/helicopter model combination in column (C) of Table 2.

2. Using service history for the trunnion, select the appropriate frequency of event hour factor from column (E) of Table 2 based on the total combined number of takeoffs and external load lifts per hour shown in column (D).

3. Multiply the value for unfactored hours TIS entered in column (C) by the appropriate value in column (E) for the frequency of event hour factor as determined in step 2. Enter the result in column (F) of Table 2. This is the total FACTORED flight hours for the particular trunnion model/helicopter model combination.

4. Enter the value for FACTORED flight hours from column (F) of Table 2 into column (C) of Table 3.

5. Using Table 3, multiply the value for FACTORED flight hours in column (C) by the appropriate RIN conversion factor listed in column (D), by the appropriate RIN adjustment factor in column (E), and enter the result in column (F). This is the accumulated RIN to-date for the particular trunnion model/helicopter model combination.

6. Add the accumulated RIN subtotals for the various trunnion model/helicopter model combinations in column (F) of Table 3 and enter the result in the space provided. This is the total accumulated RIN for the trunnion.

7. Add the factored flight hour subtotals for the various trunnion model/helicopter model combinations as determined in steps 1 through 4. This is the total revised hours TIS for the trunnion when the exact number of takeoffs and external load lifts is unknown.

Sample Trunnion Calculation

Given the following known service history for the trunnion:

Trunnion, P/N 204-011-105-001, was first purchased as a United States military surplus part with valid historical records. The trunnion had accumulated 550 hours military TIS on an Army UH-1H.

The trunnion was first installed on a restricted category UH-1H former military helicopter (1100 T.O. hp SLS rating) for 450 hours TIS. It is known that the helicopter was used primarily for aerial surveying for the first 200 hours of operation. The exact number of takeoffs and external load lifts is unknown, but it is known that the helicopter averaged less than 16 takeoffs per hour with no external load lifts. It was subsequently used for repeated heavy lift operation for the next 250 hours of operation and averaged between 25 and 31 combined takeoffs and external load lifts per hour during this period of time.

The trunnion was then removed and subsequently installed on a restricted category UH-1E former military helicopter (1100 T.O. hp SLS rating) for a total of 150 hours TIS with accurate records indicating that it experienced 100 takeoffs and 2,450 external load lifts.

Calculate the FACTORED flight hours and total accumulated RIN for the trunnion as follows:

FACTORED Flight Hours and Accumulated RIN while installed in U.S. military Model UH-1H:

Calculate FACTORED flight hours from Table 2 as follows:

FACTORED Flight Hours Start Printed Page 4891

= (unfactored hours TIS) × (frequency of event hour factor)

=(column C) × (column E)

=(550) × (1)

=550 hours

Then using Table 3, calculate the accumulated RIN as follows:

Accumulated RIN

= (FACTORED flight hours) × (RIN conversion factor) × (RIN adjustment factor)

= (column C) × (column D) × (column E)

= (550) × (20) × (1)

= 11,000 RIN

FACTORED Flight Hours and Accumulated RIN while installed in restricted category Model UH-1H:

Calculate FACTORED flight hours from Table 2 as follows:

FACTORED Flight Hours (for first 200 hours)

= (unfactored hours TIS) × (frequency of event hour factor)

= (column C) × (column E)

= (200) × (1)

= 200 hours

FACTORED Flight Hours (for next 250 hours)

= (unfactored hours TIS) × (frequency of event hour factor)

= (column C) × (column E)

=(250) × (2)

=500 hours

Then using Table 3, calculate the accumulated RIN as follows:

Accumulated RIN

= (FACTORED flight hours) × (RIN conversion factor) × (RIN adjustment factor)

= (column C) × (column D) × (column E)

= (200) × (20) × (1) + (500) × (20) × (1)

= 4,000 + 10,000

= 14,000 RIN

FACTORED Flight Hours and Accumulated RIN while installed in restricted category Model UH-1E:

Calculate the accumulated RIN from Table 1 and the given number of takeoffs and external load lifts as follows:

Accumulated RIN

= (number of takeoffs × RIN factor per takeoff) + (number of external load lifts × RIN factor per external load lifts)

= (column C) × (column D) + (column F) × (column G)

= (100) × (1.5) + (2,450) × (3)

= 7,500 RIN

Calculate the Total Accumulated RIN and Revised Hours TIS as follows:

The total accumulated RIN to-date for the trunnion is the sum of the subtotals from Tables 1 and 3.

Total Accumulated RIN

= 11,000 + 14,000 + 7,500

= 32,500

The total FACTORED flight hours for the trunnion is the sum of the subtotals from Table 2.

Total FACTORED Flight Hours

= 550 + 200 + 500

= 1,250 hours

The revised hours TIS to-date for the trunnion is the sum of the total FACTORED flight hours and the additional unfactored hours TIS for the trunnion when the exact number of takeoff and external load lifts is known.

Revised Hours TIS

= 550 + 200 + 500 + 150

= 1,250 + 150

= 1,400 hours

Both the total accumulated RIN and the revised hours TIS need to be determined and checked for exceeding the allowable life limits for the trunnion.

The values for the sample problem are shown in Tables 1-3 for illustration purposes only.

(e) This amendment becomes effective on March 8, 2002.