AMS-S-13165
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2.APPLICABLE DOCUMENTS:
The following publications, of the issues in effect on date of invitation for bids or request for proposal, form a part of this specification to the extent specified herein.
2.1U.S. Government Publications:
Available from DODSSP, Subscription Services Desk, Building 4D, 700 Robbins Avenue,
Philadelphia, PA 19111-5094.
MIL-S-851Steel Grit, Shot, and Cut Wire Shot; and Iron Grit and Shot-Blast Cleaning and
Peening
MIL-S-5002Surface Treatments and Inorganic Coatings for Metal Surfaces of Weapon
Systems
MIL-G-9954Glass Beads, For Cleaning and Peening
MIL-STD-45662Calibration Systems Requirements
RR-S-366Sieves, T est
2.2SAE Publications:
Available from SAE, 400 Commonwealth Drive, Warrendale, PA 15096-0001.
J441Cut Wire Shot
J1830Ceramic Shot for Peening
3.REQUIREMENTS:
3.1Shot:
3.1.1Material: The shot used shall be made from cast iron, cast steel, cut steel wire (or stainless cut
wire), glass, or ceramic as specified or approved. The hardness shall be determined by any of the various methods applicable to small sections at loads determined to provide a reliable conversion to Rockwell C. Steel and iron shot shall conform to MIL-S-851. For steel parts over 200,000 psi tensile strength, use hard steel shot in the range 55-65 HRC or ceramic shot, hardness
comparable to 57-63 HRC, unless otherwise specified (see 6.14). Stainless steel cut wire shot, type 302 or 304 (condition B spring temper), and carbon steel cut wire shot shall conform to
SAE J441. Glass beads shall conform to MIL-G-9954 except for sieve analysis. Ceramic beads shall meet the requirements of SAE J1830.
3.1.2Size: Unless otherwise specified, the size of shot charged into the machine, whether new shot,
used shot, or reclassified shot, shall be at the option of the contractor and shall be as specified in table II (cast sizes), table III (cut wire sizes), table IV (glass bead sizes) or table V (ceramic bead sizes).
3.1.3Shape: The shot or beads shall be free from sharp edges and inspected for deformed shapes or
broken shapes when examined per 4.3.1, 4.3.3, and figure 7. Cut wire shot, if used, shall be
preused or burnished to eliminate sharp edges (see 6.17.1). A given sample size shall contain no more than the number of unacceptable deformed shapes as shown in figure 7, and defined in
table I below (see 3.3.9).
TABLE I. Maximum allowable number of unacceptable deformed shapes
Cast Shot Sizes
Cut
Wire
Sizes
Glass
Bead
Sizes
(Inches)
Ceramic
Bead
Sizes
(Inches)
Sample
Size
(Inches)
*Maximum Allowable
Number of
Unacceptable
Deformed Shapes
930—.132-.094— 1 x 1 8 780—.111-.079— 1 x 111
660CW-62.094-.066— 1 x 116
550CW-54.079-.056— 1 x 122
460CW-47.066-.047— 1 x 132
390CW-41.056-.039— 1 x 145
330CW-35.047-.03310.0461/2 x 1/216—CW-32——1/2 x 1/218
280CW-28.039-.0278—1/2 x 1/223
230CW-23.0331-.02340.0331/2 x 1/232
190CW-20.0278-.0197—1/2 x 1/245 170—.0234-.01650.0241/4 x 1/416 130—.0197-.0139—1/4 x 1/423 110—.0165-.01170.0171/4 x 1/432
70—.0139-.0098—1/4 x 1/445——.0117-.00830.0121/8 x 1/816——.0098-.0070—1/8 x 1/822——.0083-.00590.0081/8 x 1/831
*These numbers are approximations based on approximately 10% of the actual particle count in the given sample size.
3.2Equipment:
3.2.1Automatic shot peening: The machine used for shot peening shall provide means for propelling
shot by air pressure or centrifugal force against the work, and mechanical means for moving the work through the shot stream or moving the shot stream through the work in either translation or rotation, or both, as required. The machine shall be capable of reproducing consistently the shot peening intensities required. Except for wet glass bead peening (see 3.3.9), the equipment shall continuously remove broken or defective shot so that this shot will not be used for peening.
3.2.2Computer-controlled shot peening: When specified in the contract or purchase order (see 6.2 and
6.8), the machine used for shot peening shall be as in 3.2.1 and also shall be equipped with
computer aided monitoring equipment. This equipment shall continuously monitor critical process parameters through interaction with a sensing system. The media shall be metered to each nozzle and wheel with the desired shot flow. Process parameters shall be as specified by the procuring activity (see 6.9). The machine shall be stopped immediately and corrective action shall be taken when any of the established process limits is violated. The electronic system used for monitoring and controlling shot peening shall include a data recording device which will mark (plot) process interruptions or inconsistencies, and shall be maintained for the purpose of providing a hard copy record.
3.3Procedure:
3.3.1Dimensions and condition of parts: Areas of parts to be shot peened shall be within dimensional
and surface finish requirements before peening. All heat treatment, machining and grinding shall be completed before shot peening. All fillets shall be formed, all burrs shall be removed, and all sharp edges and corners to be peened shall be provided with sufficient radii to result in complete coverage without any distortion prior to peening (see 6.15).
3.3.2Precleaning: Except as otherwise specified or permitted, all areas to be peened shall be cleaned in
accordance with MIL-S-5002. Procedures for stripping coatings shall be as specified or approved in the contract or on the applicable drawings.
3.3.3Masking: Areas of the part or work piece and the dimensional tolerances of these areas which are
designated in the contract or applicable drawing to be free from any shot peening marks shall be suitably masked or otherwise handled to protect such surfaces from the shot stream or subsequent damage. Areas not requiring peening and not required to be masked shall be considered optional.
3.3.4Magnetic particle or penetrant inspection: Except as otherwise specified, when magnetic particle
or dye penetrant inspection is required, parts shall be subjected to such inspection before peening.
3.3.5Loading: Unless otherwise specified or permitted, parts shall be free from externally applied loads
or forces during shot peening.
3.3.6Peening intensity: Unless otherwise specified on the drawing or in the contract, the intensity value
of the shot stream used on the part shall be as specified in table VI for the thickness of the material being peened. If only a minimum intensity is specified, the variation from the specified minimum intensity shall be -0, +30% rounded to the nearest unit, but in no case less than 3 intensity units (A,C, or N) unless otherwise specified. For example, a specified peening intensity of 6A would denote an arc height of 0.006-0.009 inches on the “A” specimen. Shot peening of parts shall be accomplished using the same parameters (time, distance, blast pressure, angle of incidence, etc.) as used on the test strip.
3.3.7Coverage: Areas of parts shot peened in compliance with design requirements shall be peened to
complete visual coverage (see 4.4.1 and 6.11). When a surface on which peening is required is obstructed and it is impossible to obtain complete visual coverage by direct impact, coverage by reflected shot is allowed. Full coverage will not be required if the part is peened only for forming or straightening. Critical applications shall be as specified by the procuring activity (see 4.2 and 6.11).
3.3.7.1Boundary variation: Unless otherwise specified, the variation in boundaries of areas to be
peened, when limited, shall be -0 to +1/8 inch.
3.3.7.2Fillets and shielded areas: Unless otherwise specified, the nominal size of shot used on fillet
surfaces shall not be greater than one-half the fillet radius. For slots or other apertures, through which shot must pass to peen shielded critical areas, the nominal shot diameter shall not be
greater than 1/4 the diameter or width of such aperture.
3.3.8Minimum shot size for peening materials: Except as otherwise specified or permitted, or in cases
such as when shielded areas are involved, materials shall not be peened with shot smaller than the following for the intensities given:
Intensity Peening Media
.012A S-280 or CW-28 or GB (.039-.028) or ceramic bead size .033
.016A S-390 or CW-41 or GB (.056-.039) or ceramic bead size .046
.020A S-550 or CW-54 or GB (.079-.056)
3.3.9Shot maintenance: The shot or beads shall be maintained in the machine so that not more than
20% of the particles, by weight, shall pass through the sieve number specified in table VII for the shot size used. Metallic shot shall be checked at least every eight hours of operation to assure that not more than 10% of the shot by actual count is deformed or broken; glass beads shall be
checked at least every two hours of operation to assure that not more than 10% of the beads by actual count are deformed or broken (see 3.1.3 and table I). When wet glass peening is used, the entire slurry charge shall be changed at least every two hours for compliance with this requirement.
Ceramic beads shall be checked at least every four hours to assure that not more than 5% of the beads by actual count are deformed or broken. In all cases, at least one determination shall be made at the beginning and one at the end of each period of operation or part change.
3.3.10Post treatments: No manufacturing operations which relieve stresses developed by peening or
which develop detrimental residual stresses shall be permitted after shot peening. When peened parts are heated after shot peening as for baking of protective coatings, to relieve hydrogen
embrittlement after electroplating, or other thermal treatment, the temperatures employed shall be limited as follows (see 6.13):
Material Temperature
Steel parts* 475°F maximum
Stainless steel parts** 750°F maximum
Aluminum alloy parts 200°F maximum
Magnesium alloy parts 200°F maximum
Titanium alloy parts 600°F maximum
Nickel alloy parts1000°F maximum
Cobalt alloy parts1000°F maximum
*Except 300°F for steel parts that are
tempered below the recommended 475°F
maximum, after a quench hardening
operation.
**Except 475°F for PH steels and cold
worked 300 series stainless steels.
3.3.10.1Residual shot removal: After shot peening and removal of protecting masks, all shot and shot
fragments shall be removed from surfaces of articles. Only methods which will not erode or
scratch surfaces shall be used.
3.3.10.2Cleaning: Aluminum alloy parts which have been peened with metallic shot shall be chemically
cleaned by a preapproved cleaning procedure.
3.3.10.3Protection from corrosion: Shot peened parts shall be protected from corrosion during
processing and until final coating or packaging is completed. The method of protection shall be as specified or approved in the contract or purchase order.
4.QUALITY ASSURANCE PROVISIONS:
4.1Responsibility for inspection:
Unless otherwise specified in the contract or purchase order, the contractor is responsible for the performance of all inspection requirements (examinations and tests) as specified herein. Except as otherwise specified in the contract or purchase order, the contractor may use his own or any other facilities suitable for the performance of the inspection requirements specified herein, unless
disapproved by the Government. The Government reserves the right to perform any of the
inspections set forth in this specification where such inspections are deemed necessary to ensure supplies and services conform to prescribed requirements.
4.1.1Responsibility for compliance: All items shall meet all requirements of section 3. The inspection
set forth in this specification shall become a part of the contractor’s overall inspection system or quality program. The absence of any inspection requirements in the specification shall not relieve the contractor of the responsibility of ensuring that all products or supplies submitted to the
Government for acceptance comply with all requirements of the contract. Sampling inspection, as part of manufacturing operations, is an acceptable practice to ascertain conformance to
requirements, however, this does not authorize submission of known defective material, either
indicated or actual, nor does it commit the Government to accept defective material.
4.2Shot peening intensity:
Unless otherwise specified on the drawing or in the contract, the peening intensity value used on the part shall be as specified in table VI for the material thickness involved; and peening intensities shall be monitored at all locations specified by the procuring activity in accordance with 4.2.4 (see6.5). 4.2.1Sampling: At least one intensity determination shall be made to represent each machine for each
two hours of continuous operation or fraction thereof where glass beads are used, for each four hours of continuous operation or fraction thereof where ceramic beads are used, and for each eight hours of continuous operation or fraction thereof where cast steel, cast iron, or cut steel wire (or stainless cut wire) shot is used. In all cases, at least one determination shall be made at the
beginning and one at the end of each period of operation or part change.
4.2.2Test strip specimens: A test strip specimen is an Almen test strip used to measure “intensity.” At
least two test strip specimens conforming in dimensions and mechanical properties to figures 1, 2 or 3 shall be used for each intensity determination at each location.
4.2.3Saturation curve: For initial process development, a saturation curve shall be generated for each
location where intensity is to be verified. A curve is produced by exposing individual test strips for increasing time periods and plotting the results (exposure time vs. arc height). A minimum of four points other than zero shall be used to define the curve; one of the four points used to indicate
saturation shall be at least double the time of the saturation point. Saturation is achieved when, as the exposure time for the test strips is doubled, the arc height does not increase by more than 10% (see figure 8 and 6.12). The arc height at saturation for each location must be within the required arc height range for that location. The reuse of test strips is not permitted.
4.2.4Test procedure: The test strip specimens selected in accordance with 4.2.1 shall be attached as
shown in figure 5, to holders of the form and dimensions shown in figure 4, and mounted on a
fixture or article and exposed to the shot stream in a manner which simulates conditions used for the articles. The test strips shall be run for the saturation time established by the saturation curve (see 4.2.3). After exposure the test strips shall be removed from the holders and the amount of deflection measured with a micrometer gage, of the form and dimensions shown in figure 6. The arc height or amount of deflection measured on the test strips shall be within the specified intensity range (see 3.3.6). If the arc height measured is not within the intensity range specified, the
process parameters must be adjusted and new saturation curves must be run (see 4.2.3). In using the micrometer gage, the central portion of the unpeened side of the test strip shall be placed
against the indicator stem of the gage. A peened test strip shall not be re-peened after being
removed from the test strip holder.
4.2.5Test records: Test strip specimens and test records shall accompany peened parts, and shall be
inspected along with the appropriate lot. The following information shall be recorded for each
specimen:
(a)Lot number and other production control numbers
(b)Part number
(c)Number of parts in lot
(d)Date peened
(e)Shot peening machine used and machine settings
(f)Specified peening intensity and actual peening intensity by test strip identification numbers if
test fixture requires use of more than one strip
(g)Shot size, type, hardness, standoff (distance), length of time of exposure to shot stream, and
shot flow rate (see 6.17.6)
(h)Percent coverage
(i)Shot velocity or air pressure
4.2.6Computer-controlled shot peening: When auxiliary computer controlled equipment is used,
calibration of the monitoring systems shall be in accordance with MIL-STD-45662. Intensity
verification as per 4.2.4 shall be done prior to initial operation and after any calibration.
4.3Shot size and uniformity:
4.3.1Sampling: Sampling for shot size and uniformity shall be at the frequencies specified in 4.2.1 for
intensity. Where cut wire shot is used, it shall be inspected for absence of sharp edges and
roundness (see 3.1.3).
4.3.2Test procedure: Tests for shot size and uniformity for compliance with the requirements of 3.1 shall
be made using sieves conforming to Federal Specification RR-S-366.
4.3.3Visual examination (sample size): Samples of shot for visual examination shall consist of the
number of shot in one layer which completely fills an area of 1, 1/2, 1/4, or 1/8 inch square as
applicable (see table I). If feasible a minimum of 100 beads or pieces of shot shall constitute a
single sample (see 6.16). Acceptable and unacceptable shapes are shown in figure 7.
4.4Inspection of shot peened articles:
4.4.1Coverage: Unless otherwise specified articles shall be 100% visually inspected for compliance with
the coverage requirements of 3.3.7 using either method described in 6.11a or 6.11b.
4.4.2Corrosion protection: Articles shall be inspected for compliance with the method of protection
specified in the contract or purchase order.
5.PACKAGING:
This section is not applicable to this specification.
6.NOTES:
(This section contains information of a general or explanatory nature that may be helpful, but is not mandatory.)
6.1Intended use:
Shot peening is intended to induce surface compressive stresses in metal parts which are subjected to repeated applications of complex load patterns such as axles, springs (helical, torsional and leaf), gears, shafting, aircraft landing gear, structural parts, etc., for the purpose of improving resistance to fatigue and stress corrosion cracking. Ceramic and glass bead peening, either wet or dry, is used when iron contamination of non-ferrous parts is a consideration.
6.2Acquisition requirements:
The following will be as specified or approved in the contract or in the applicable drawings:
(a)Title, number, and date of this specification
(b)Issue of DODISS to be cited in the solicitation, and if required, the specific issue of individual
documents referenced (see 2.1.1 and 2.2)
(c)The type of shot to be used (see 3.1.1)
(d)Shot size (and hardness if cast steel shot is to be used), if particular size required (see 3.1.2,
3.3.7.2, 3.3.8 and 6.7)
(e)Type of equipment to be used - automatic or computer controlled (see 3.2.1 and 3.2.2)
(f)Methods for cleaning surfaces and methods for stripping coatings, if applicable (see 3.3.2)
(g)Designation of locations to be peened (including intensity verification areas), or locations to be
free from peening as applicable (see 3.3.3)
(h)If magnetic particle or dye penetrant inspection is required on peened parts (see 3.3.4)
(i)If externally applied forces are permissible during peening (see 3.3.5)
(j)Intensity requirements if other than 3.3.6
(k)Over performance peening coverage when required to insure 100% coverage for performance on critical applications (see 3.3.7)
(l)Method of coverage verification (see 3.3.7 and 6.11)
(m)Shot size limitations in obstructed areas, boundaries, and other peening operations (see3.3.8) (n)Specific cleaning formulation(s) or approved cleaning procedure for peened parts, if applicable (see 3.3.10.2)
(o)Method of protecting shot peened parts from corrosion (see 3.3.10.3)
6.3Effective peening:
Shot peening, to have the desired effect, requires that the specified intensity and coverage be
achieved on critical areas (see 6.17.3), where high tensile stresses or stress ranges are most likely to cause fatigue or stress corrosion failures in service.
6.4Special peening procedure:
Where a special procedure is required, applicable drawings or a contract will designate such critical areas (see 4.2).
6.5Additional peening:
Shielded or partially shielded areas, walls of deep recesses, or other areas less accessible to the maximum effect of the blast stream will receive less peening as to intensity and coverage than more exposed or more favorably oriented areas, and may therefore require additional peening or
repositioning of the part to achieve correct peening in these areas. Use of special nozzle equipment or employment of deflector peening operations may be useful in diminishing the amount of additional peening.
6.6Peening in thin sections:
The peening of very thin or small sections to high intensities should be avoided because of the
distortion and high residual tensile stresses in the core material that may result from such peening.
6.7Shot size selection:
In selecting shot sizes, consideration should be given to the following factors:
(a)Shape of parts
(b)Size of fillets (small shot to get into small fillets, etc.) (see 3.3.7.2)
(c)Intensity desired (the size of shot limits the intensity which can be obtained in a given peening
machine). Therefore, it may be necessary to use a larger shot to obtain a higher intensity or to reduce intensity requirements when shot must be small for consideration (b)
(d)Finish (at equal intensities larger shot will produce a finer surface finish)
(e)Whether or not to use small shot at high intensity on aluminum or magnesium alloy parts
6.8Computer-controlled shot peening selection:
Computer-controlled shot peening equipment should be considered for use in the following
instances:
(a)Man flight vehicle components
(b)Components where shot peening is used as part of the design strength of the component
(c)Components which are considered critical to system success
6.9Process parameters:
Parameters which may affect the shot peening process include, but are not limited to, the following:
(a)Shot flow rate
(b)Air pressure or wheel speed (RPM)
(c)Impact angle
(d)Distance of nozzle(s) or wheel(s) from workpiece
(e)Relative motion between workpiece and nozzle(s) or wheel(s)
Shot peening procedures should be as agreed upon between the contractor and the procuring
activity and will comply with the process parameters established in 3.2.2 and 3.3.
6.10Intensity comparisons:
For comparisons of the nominal intensity designations, type C test specimen deflection may be multiplied by 3.5 to obtain the approximate deflection of a type A test strip. Test strip “A” is ordinarily used for arc heights up to 0.024 inches; for higher intensity peening, test strip C is used. For
intensities below .004A the type “N” test strip should be used. For comparison of the nominal
intensity designations, type “A” test strip deflection may be multiplied by three to obtain the
approximate deflection of a type “N” test strip (see figures 1, 2 and 3).
6.11Coverage:
Complete visual coverage is defined as a uniform and complete denting or obliterating of the original surface of the part or work piece as determined by either of the following methods:
(a)Visual examination using a ten power magnifying glass.
(b)Visual examination using a ten power magnifying glass in conjunction with an additional visual
examination using an approved liquid tracer system (see 6.17.4) may be used for process control by the contractor. Unless otherwise specified, the procedure for using an approved liquid tracer system is described as follows:
Prepare a control specimen of the actual work piece. Coat this control specimen with tracer
liquid by dipping, spraying, or painting and allow the liquid to dry. Check the specimen under a light (an ultraviolet light is used for a fluorescent tracer system) to insure that complete coating of the area to be shot peened has been accomplished. This control specimen is shot peened using the correct intensity and parameters specified for complete coverage and is then re-examined
under the light (or ultraviolet light) in order to determine if the tracer residue has been completely removed. Full coverage is indicated by complete removal of the tracer residue. Coverage of
actual production pieces can be established by using the same procedure used for control
specimens. This can be done by utilizing the liquid tracer for each part or on a statistical
sampling basis.
NOTE:The liquid tracer system must be approved by the procuring activity. Data, showing that 100% coverage of the part is obtainable by using this tracer system, is required.
6.12Intensity:
Intensity can only be established by plotting a saturation curve, as shown in figure 8, and assuring that the required intensity (determined by the arc height of the test strip) falls on the right side of the knee of the curve. By doubling the time of exposure, the arc height of a test strip should not increase by more than 10%.
6.13Process temperatures:
Processing or service temperatures of shot peened parts shall be limited to the temperatures in
3.3.10 unless test data for specific applications support the satisfactory use of higher temperatures.
NOTE:Operations performed after shot peening such as auxiliary electrodeposited coatings may cause tensile stresses on the steel surface. Procedures for relieving these stresses will be
specified in the contract, or part drawing, or will be in accordance with the applicable
specification.
6.14Multiple exposure times:
Although test strips peened to saturation generally exhibit complete (100%) visual coverage,
additional factors may need to be built into the contractor’s process or procedure which will insure that minimum coverage has been specified for the peening of steels over 200,000 psi tensile
strength and/or for critical applications when over performance peening is required to insure
complete coverage (see 3.3.7). Unless otherwise specified the factors required to achieve 100% coverage is the responsibility of the contractor.
6.15Condition of material before peening:
For informational purposes, MIL-P-81985, the military specification for peening of metals, discusses the condition of material prior to peening.
6.16Examination of shot sample:
It may be necessary to use a lighted binocular microscope to inspect the smaller shot for size and uniformity (see 4.3.3).
6.17Definitions:
6.1
7.1Burnishing: Burnishing is the smoothing of surfaces by rubbing or tumbling, accomplished chiefly
by the movement rather than the removal of the surface layer.
6.1
7.2Contractor: An individual or organization outside the U.S. Government which has accepted any
type of agreement or order for providing research, supplies, or services to a U.S. Government
agency.
6.1
7.3Critical: The term critical, as in critical areas, is where a failure of any portion would cause loss of
system, loss of major component, or loss of personnel.
6.1
7.4Liquid tracer system: A tracer system that employs liquid coating material which removes at a rate
proportioned to peening coverage. A fluorescent tracer system has, in addition, a pigment which fluoresces under ultraviolet light.
6.1
7.5Procuring activity: The term procuring activity is that activity of the Government which actually
initiates the request for procurement and maintains the records of the procurement.
6.1
7.6Standoff: Standoff is the distance from the shot nozzle to the surface being peened.
6.18Subject term (key word) listing:
Almen test strip
Fluorescent Tracer System
Liquid Tracer System
Peening intensity
Saturation curve
Shot peening
Shot size
PREPARED UNDER THE JURISDICTION OF AMS COMMITTEE “B”
TABLE II. Cast shot numbers and screening tolerances.
Peening Shot
All pass
U.S. sieve
Number and
opening 1/
Max 2% on
U.S. sieve
Number and
opening 1/
Max. 50% on
U.S. sieve
Number and
opening 1/
Cumulative
min. 90% on
U.S. sieve
Number and
opening 1/
Cumulative
min. 98% on
U.S. sieve
Number and
opening 1/
930 5 (.157) 6 (.132) 7 (.11) 8 (.0937) 10 (.0787) 780 6 (.132) 7 (.11) 8 (.0937)10 (.0787) 12 (.0661) 660 7 (.11) 8 (.0937)10 (.0787)12 (.0661) 14 (.0555) 550 8 (.0937)10 (.0787)12 (.0661)14 (.0555) 16 (.0469) 46010 (.0787)12 (.0661)14 (.0555)16 (.0469) 18 (.0394) 39012 (.0661)14 (.0555)16 (.0469)18 (.0394) 20 (.0331) 33014 (.0555)16 (.0469)18 (.0394)20 (.0331) 25 (.0278) 28016 (.0469)18 (.0394)20 (.0331)25 (.0278) 30 (.0234) 23018 (.0394)20 (.0331)25 (.0278)30 (.0234) 35 (.0197) 19020 (.0331)25 (.0278)30 (.0234)35 (.0197) 40 (.0165) 17025 (.0278)30 (.0234)35 (.0197)40 (.0165) 45 (.0139) 13030 (.0234)35 (.0197)40 (.0165)45 (.0139) 50 (.0117) 11035 (.0197)40 (.0165)45 (.0139)50 (.0117) 80 (.0070) 7040 (.0165)45 (.0139)50 (.0117)80 (.0070)120 (.0049)
1/ Sieve numbers specified in RR-S-366, number in parenthesis represents sieve opening size (inches).
TABLE III. Cut wire shot (steel/stainless) size classification.
Shot No.Wire diameter,
inches
Weight of
fifty pieces
grams 1/
Length of
ten pieces
inches 2/
CW-62.062 ± .002 1.09 to 1.33.620 ± .040
CW-54.054 ± .0020.72 to 0.88.540 ± .040
CW-47.047 ± .0020.48 to 0.58.470 ± .040
CW-41.041 ± .0020.31 to 0.39.410 ± .040
CW-35.035 ± .0010.20 to 0.24.350 ± .030
CW-32.032 ± .0010.14 to 0.18.320 ± .030
CW-28.028 ± .0010.10 to 0.12.280 ± .030
CW-23.023 ± .0010.05 to 0.07.230 ± .020
CW-20.020 ± .0010.04 to 0.05.200 ± .020
1/ Fifty randomly selected particles shall be weighed. The total weight of the fifty pieces shall be within the limits specified in table III above.
2/ Ten randomly sampled shot particles shall be checked for length. All ten pieces selected for this test shall fall within the tolerance shown in table III above.
T ABLE IV. Glass bead sizes.
Nominal glass bead size
(inches)Min 99% shall
pass sieve
number 1/
Min 95% shall
pass sieve
number 1/
Max 10% shall
pass sieve
number 1/
Max 5% shall
pass sieve
number 1/
Max Min
.132.094 5 6 8 10 .111.079 6 7 10 12 .094.066 7 8 12 14 .079.056 8 10 14 16 .066.047 10 12 16 18 .056.039 12 14 18 20 .047.0331 14 16 20 30 .039.0278 16 18 25 40 .0331.0234 18 20 30 45 .0278.0197 20 25 35 50 .0234.0165 25 30 40 60 .0197.0139 30 35 45 70 .0165.0177 35 40 50 70 .0139.0098 40 45 60 80 .0117.0083 45 50 70100 .0098.0070 50 60 80120 .0083.0059 60 70100140 .0070.0049 70 80120170 .0059.0041 80100140200 .0049.0035100120170230 .0041.0029120140200280 .0035.0024140170230325 .0029.0021170200270400 .0024.0021200230325400
1/ Sieve numbers specified in RR-S-366.
T ABLE V. Ceramic bead sizes.
NOMINAL SIZES
(inches)
SIEVE NUMBER AND SIEVE
OPENING SIZE (in inches) 1/
Max 0.5%
Retains
Max 5%
Retains
Max 10%
Pass
Max 3%
Pass
0.04614 (.0555)16 (.0469) 20 (.0331) 25 (.0278)
0.03318 (.0394)20 (.0331) 30 (.0234) 40 (.0165)
0.02425 (.0278)30 (.0234) 40 (.0165) 50 (.0117)
0.01735 (.0197)40 (.0165) 50 (.0117) 60 (.0098)
0.01245 (.0139)50 (.0117) 70 (.0083) 80 (.0070)
0.00860 (.0098)70 (.0083)100 (.0059)120 (.0049) 1/ Sieve numbers specified in RR-S-366.
T ABLE VI. Shot peening intensity.
Material 1/Steel under
200,000 psi
Steel over
200,000 psi 4/
Titanium and
Titanium alloys
Aluminum alloys
(metallic shot/
ceramic shot) 5/
Aluminum alloys
(non metallic shot)
Under .090 inch
thickness
———.004 to .008 N
.090 to .375
inch thickness
.008 to .012 A 2/.006 to .010 A.006 to .010 A.008 to .012 N
Over .375 inch
thickness
.012 to .016 A 3/.006 to .010 A.010 to .014 A.012 to .016 N
1/ Magnesium alloys response to shot peening is different from the response of other materials. It is essential to avoid broken or deformed peening material. Peening must be done with materials and under conditions which do not induce cracks.
2/ The suffix letter A indicates that the values have been determined by the use of test strip A (see figure 1).
3/ Test strip A is used for arc heights up to 0.024 inches. For greater peening intensity test strip C should be used. Test strip N is used if the intensity is less than .004 inches on the A strip (see figures 2 and 3).
4/ For steel over 200,000 psi, use hard shot or ceramic shot (see 3.1.1). Unless otherwise specified on the drawing or in the contract, the peening intensity shall be as specified in table VI above.
5/ If steel shot is used, the areas peened should be chemically decontaminated to remove residual iron left on the part. If ceramic shot is used for these intensities no decontamination is required since the shot for the specified material thickness is non-metallic.