1、Designation: D 6841 03Standard Practice forCalculating Design Value Treatment Adjustment Factors forFire-Retardant-Treated Lumber1This standard is issued under the fixed designation D 6841; the number immediately following the designation indicates the year oforiginal adoption or, in the case of rev
2、ision, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon (e) indicates an editorial change since the last revision or reapproval.1. Scope1.1 This practice covers procedures for calculating treat-ment adjustment factors to be applied to des
3、ign values forfire-retardant-treated lumber used at ambient temperaturesservice temperatures up to 100F (38C) and as framing inroof systems.1.2 These design value treatment adjustment factors for theproperties of extreme fiber in bending, tension parallel to grain,compression parallel to grain, hori
4、zontal shear and modulus ofelasticity are based on the results of strength tests of matchedtreated and untreated small clear wood specimens after condi-tioning at nominal room temperatures 72F (22C) and ofother similar specimens after exposure at 150F (66C). Thetest data are developed in accordance
5、with Test MethodD 5664. Guidelines are provided for establishing adjustmentfactors for the property of compression perpendicular to grainand for connection design values.1.3 Treatment adjustment factors for roof framing applica-tions are based on computer generated thermal load profiles fornormal wo
6、od roof construction used in a variety of climates asdefined by weather tapes of the American Society of Heating,Refrigerating and Air-Conditioning Engineers, Inc.(ASHRAE).2The solar loads, moisture conditions, ventilationrates and other parameters used in the computer model wereselected to represen
7、t typical sloped roof designs. The thermalloads in this practice are applicable to roof slopes of 3 in 12 orsteeper, to roofs designed with vent areas and vent locationsconforming to national standards of practice and to designs inwhich the bottom side of the roof sheathing is exposed toventilation
8、air. For designs that do not have one or more ofthese base-line features, the applicability of this practice needsto be documented by the user.1.4 The procedures of this practice parallel those given inPractice D 6305. General references and commentary in Prac-tice D 6305 are also applicable to this
9、 practice.1.5 This practice is written in inch-pound units with SI unitsprovided in parentheses for information only.1.6 This standard does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this standard to establish appro-priat
10、e safety and health practices and determine the applica-bility of regulatory limitations prior to use.2. Referenced Documents2.1 ASTM Standards:D 9 Terminology Relating to Wood3D 5664 Test Method for Evaluating the Effects of Fire-Retardant Treatments and Elevated Temperatures onStrength Properties
11、of Fire-Retardant-Treated Lumber3D 6305 Practice for Calculating Bending Strength DesignAdjustment Factors for Fire-Retardant-Treated PlywoodRoof Sheathing33. Terminology3.1 Definitions:3.1.1 Definitions used in this practice are in accordance withTerminology D 9.3.2 Definitions of Terms Specific to
12、 This Standard:3.2.1 bin mean temperature10F (5.5C) temperatureranges having mean temperatures of 105 (41), 115 (46), 125(52), 135 (57), 145 (63), 155 (68), 165 (74), 175 (79) and185F (85C).3.2.2 thermal load profilethe cumulative time per year ineach 10F (5.5C) temperature bin.4. Summary of Practic
13、e4.1 Test results developed in accordance with Test MethodD 5664 are used in conjunction with computer generatedthermal load profiles to calculate treatment factors that areapplied to published design values for untreated lumber. Thesetreatment adjustment factors account for the combined effect offi
14、re-retardant-treatment and service temperatures.5. Significance and Use5.1 Fire-retardant-treatments are used to reduce the flame-spread characteristics of wood. Chemicals and redrying condi-tions employed in treatments are known to modify the strengthproperties of the wood product being treated. Th
15、is practice1This practice is under the jurisdiction of ASTM Committee D07 on Wood andis the direct responsibility of Subcommittee D07.07 on Fire Performance of Wood.Current edition approved April 10, 2003. Published June 2003. Originallyapproved in 2002. Last previous edition approved in 2002 as D 6
16、841-02.2American Society of Heating, Refrigerating, and Air-Conditioning Engineers,Inc. (ASHRAE), 1791 Tullie Circle, NE, Atlanta, GA 30329.3Annual Book of ASTM Standards, Vol 04.10.1Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.giv
17、es procedures for fire-retardant chemical manufacturers touse to calculate the effects of their treatment on lumber used innormal and elevated temperature service conditions.5.2 The effect of fire-retardant treatments on the strength oflumber used in roof framing applications is time related. In thi
18、spractice, the cumulative effect on strength of annual thermalloads from all temperature bins is increased 50 times toestablish treatment adjustment factors for fire-retardant treatedlumber roof framing.5.3 The procedures of Test Method D 5664 employ anelevated temperature intended to produce streng
19、th losses in ashort period of time. Although the exposure is much moresevere than that which occurs in an actual roof system, thechemical reactions that occur in the laboratory test are consid-ered to be the same as those occurring over long periods oftime in the field.5.4 Treatment adjustment facto
20、rs developed under this prac-tice apply to lumber installed in accordance with constructionpractices recommended by the fire-retardant chemical manu-facturer which include avoidance of direct wetting, precipita-tion or frequent condensation. Application of this practice islimited to roof application
21、s with design consistent with 1.3.6. Test Data6.1 Test Method D 5664 describes the procedures used toobtain the data needed to calculate the ratios of average treatedand average untreated values for the strength properties.6.1.1 Procedure 1 of Test Method D 5664 provides data forcomparing the initia
22、l effects of fire-retardant treatments tountreated controls for bending, tension parallel, compressionparallel, and horizontal shear properties. The procedure usessmall clear specimens.6.1.2 Procedure 2 of Test Method D 5664 provides data forassessing the differential trends between treated and untr
23、eatedspecimens on bending and tension parallel properties over thecourse of a prolonged exposure to elevated temperature. Theprocedure uses small clear specimens.6.1.3 Procedure 3 of Test Method D 5664 is an optionalprocedure to provide additional information on size effects.The results are used to
24、modify the test results for the smallclear specimens of Procedure 1 and 2.6.2 Specimens subjected to prolonged exposure to elevatedtemperature are exposed in a controlled environment of 150 64F (66 6 2C) and $ 50 % relative humidity. Durations ofexposure are 36, 72, and 108 days.7. Calculation of St
25、rength Loss Rates7.1 For each species and property evaluated, calculate theratio of the average treated value to the average untreated valuefor the specimens conditioned at room temperature only(unexposed specimens) and for specimens exposed for thesame period of time at elevated temperature.7.1.1 T
26、he treated and untreated specimen averages used tocalculate each ratio shall include the same number of speci-mens and each treated specimen value shall be matched to anuntreated specimen value obtained from the same source pieceof lumber.NOTE 1Test data show that the ratio of average treated and av
27、erageuntreated values is a more conservative measure of treatment effect thanthe median or the average of the individual matched specimen ratios.7.2 The ratio of the average property value for unexposedtreated specimens to the average value for unexposed untreatedspecimens shall be designated the in
28、itial treatment ratio, Ro.7.3 Using the ratios of average treated to untreated speci-mens exposed to elevated temperature for the same period oftime, Rti, determine by least squares the linear regression.Rti5 a 1 ktD! (1)where:Rti= ratio of average treated to untreated values,D = number of days spec
29、imens exposed at elevated tem-perature,a = intercept, andkt= slope, strength loss rate.7.3.1 The ratio, Ro, for unexposed specimens (conditionedat room temperature only) shall be included in the regressionanalysis.7.3.2 A property for which the strength loss rate, kt,isnotnegative is assumed to be u
30、naffected by the elevated tempera-ture exposure.7.3.3 The strength loss rate, kt, shall be adjusted to a 50percent relative humidity (RH) basis by the equation:k505 kt50/RHi! (2)where:k50= strength loss rate at 50 % RH, andRHi= elevated temperature test RH.7.4 Calculate strength loss per day rates f
31、or bin meantemperatures of 105 (41), 115 (46), 125 (52), 135 (57), 145(63), 155 (68), 165 (74), 175 (79), and 185F (85C) using theArrhenius equation:ln k50/k2! 5 EaT12 T2!# / RT1T2(3)where:k2= strength loss rate at bin mean temperature,Ea= 21 810 cal/mol, (1)4,5(91 253 J/mol),R = 1.987 cal/mol-K (8.
32、314 J/mol-K), gas constant,T1= test temperature, K, andT2= bin mean temperature, K.7.4.1 Where the treatment effect was evaluated at more thanone elevated temperature for example 130F (54C) and150F (66C), the strength loss rates associated with the binmean temperatures shall be calculated for each t
33、emperatureseparately and the rates averaged for determination of capacityloss values associated with thermal load profiles.NOTE 2This practice constructs an Arrhenius plot using classicalchemical kinetics techniques, which is the simplest modeling approach.Other more sophisticated modeling technique
34、s are available but require adifferent procedure for calculating strength loss rate (2, 3).64The boldface numbers in parentheses refer to a list of references at the end ofthis standard.5Pasek and McIntyre have shown that the Arrhenius parameter, Ea, forphosphate-based retardants for wood averages 2
35、1 810 cal/mol (91 380 J/mol.).6A description of other models is available in Refs (2,3).D68410328. Calculating Capacity Loss for Roof FramingApplications8.1 Thermal load profiles applicable to roof framing aregiven in Table 1. The loads represent the cumulative days peryear framing temperatures fall
36、 within 10F (5.5C) of the binmean temperatures of 105 (41), 115 (46), 125 (52), 135 (57),145 (63), 155 (68), 165 (74), 175 (79) and 185F (85C).Tabulated values are based on a verified attic temperature andmoisture content model developed by the USDA, ForestService Forest Products Laboratory (4) and
37、reference yearweather tapes. Input parameters used in the model werea3in12 roof slope, south exposure, roofing absorptive factor of 0.65and ventilation rate of 8 air changes per hour (ach).NOTE 3Additional information on the computer model and the inputparameters used is given in Practice D 6305.8.1
38、.1 Two thermal load profiles are given in Table 1. Thisfirst profile shall be used with all properties except tensionparallel to grain. This profile represents a weighted average ofbin temperature days for the bottom of the roof sheathing andfor the attic air with weights of 0.25 and 0.75 respective
39、ly. Thesecond load profile shall be used for tension parallel to grainand is based on bin temperature days for the attic air.NOTE 4Field temperatures for upper and lower chords of roof rafters(truss) for two locations have been studied (5) (Fig. 1). This data indicatesthat the upper chord temperatur
40、e tracks closely with the attic airtemperature. The use of a weighted average of bottom sheathing and atticair temperatures for properties other than tension parallel to grainrepresent a conservative approach for locations where field data is notavailable.NOTE 5Thermal load profiles in Practice D 63
41、05 represent the bin-ning of the average of the hour by hour temperatures at the top and bottomof the roof sheathing.NOTE 6Thermal loads in Table 1 have been indexed to a 50 percentrelative humidity basis by multiplying model generated loads by the ratioof the time weighted average attic relative hu
42、midity for all temperatures of80F and above and 50 percent. The adjustment is based on the use of alinear adjustment of test strength loss rates for relative humidity and theuse of a linear regression model to characterize strength loss over time.8.2 Calculate capacity loss for each property as the
43、negativevalue of the rates (k2) as determined in 7.4 for each bintemperature by the cumulative days per year for that bin for theapplicable zone and property from Table 1. The summation ofthe capacity loss values for each temperature bin shall bedesignated as the total annual capacity loss (CLT) for
44、 thatproperty and zone.9. Treatment Adjustment Factors9.1 For each property and zone, a treatment adjustmentfactor for design values shall be calculated as:TF 5 1 2 IT 2 nCF!CLT!# (4)where:TF = treatment adjustment factor = (1 IT),IT = initial treatment effect=1Ro,n = number of iterations = 50,CF =
45、cyclic loading factor = 0.6, andCLT = total annual capacity loss.9.1.1 Where a property has been evaluated at more than oneelevated temperature, IT in Eq 4 shall be taken as the averageof the Roratio for each temperature data set.9.2 Where the properties of compression parallel to grainand horizonta
46、l shear have not been evaluated at elevatedtemperatures for a species, the CLT determined for bending andfor tension parallel to grain, whichever is greater, shall be usedin Eq 4 to determine treatment adjustment factors for theseproperties.9.3 Where a property shows no strength loss when exposedat
47、elevated temperature (CLT = 0), the property treatmentadjustment factor, TF, for all thermal load zones shall be equalto (1 IT), or Ro.9.4 A treatment adjustment factor for applications involvingservice temperatures up to 100F (38C) shall be (1 IT), orRo, for all properties.9.5 Compression perpendic
48、ular to the grain design valuesare based on a deformation limit which is related to specificgravity. Although reductions in specific gravity are generallynot observed at 150F (66C) temperature exposure, a TF of0.95 shall be used for this property for both normal temperatureand roof framing applicati
49、ons.9.6 Connection design values for lumber are related to bothspecific gravity and compression properties. The treatmentadjustment factor for lumber connections shall be either thecompression parallel to grain treatment factor or 0.90, which-ever is lower.NOTE 7The 0.90 factor has been used in practice for many years as aconservative adjustment for connection design loads for fire-retardanttreated lumber.9.7 If the effect of a fire-retardant treatment on southernpine, Douglas fir and white spruce (or spruce-pine-fir fromwhich pin
