1、Designation: D5741 96 (Reapproved 2017)Standard Practice forCharacterizing Surface Wind Using a Wind Vane andRotating Anemometer1This standard is issued under the fixed designation D5741; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revis
2、ion, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 This practice covers a method for characterizing surfacewind speed, wind direction, peak one-minute s
3、peeds, peakthree-second and peak one-minute speeds, and standard devia-tions of fluctuation about the means of speed and direction.1.2 This practice may be used with other kinds of sensors ifthe response characteristics of the sensors, including theirsignal conditioners, are equivalent or faster and
4、 the measure-ment uncertainty of the system is equivalent or better thanthose specified below.1.3 The characterization prescribed in this practice willprovide information on wind acceptable for a wide variety ofapplications.NOTE 1This practice builds on a consensus reached by the attendeesat a works
5、hop sponsored by the Office of the Federal Coordinator forMeteorological Services and Supporting Research in Rockville, MD onOct. 2930, 1992.1.4 The values stated in SI units are to be regarded asstandard. No other units of measurement are included in thisstandard.1.5 This standard does not purport
6、to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.1.6 This international standard was developed in a
7、ccor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for theDevelopment of International Standards, Guides and Recom-mendations issued by the World Trade Organization TechnicalBarriers to Trade (TBT) Committee.2. Referenced Documents2.1
8、ASTM Standards:2D1356 Terminology Relating to Sampling and Analysis ofAtmospheresD5096 Test Method for Determining the Performance of aCup Anemometer or Propeller AnemometerD5366 Test Method for Determining the Dynamic Perfor-mance of a Wind Vane3. Terminology3.1 DiscussionFor terms that are not def
9、ined herein, referto Terminology D1356.3.2 Definitions of Terms Specific to This Standard:3.2.1 aerodynamic roughness length (z0, m )a character-istic length representing the height above the surface whereextrapolation of wind speed measurements, below the limit ofprofile validity, would predict the
10、 wind speed would becomezero (1).3It can be estimated for direction sectors from alandscape description.3.2.2 damped natural wavelength (d, m)a characteristicof a wind vane empirically related to the delay distance and thedamping ratio. See Test Method D5366 for test methods todetermine the delay di
11、stance and equations to estimate thedamped natural wavelength.3.2.3 damping ratio (, dimensionless)the ratio of theactual damping, related to the inertial-driven overshoot of windvanes to direction changes, to the critical damping, the fastestresponse where no overshoot occurs. See Test Method D5366
12、for test methods and equations to determine the damping ratioof a wind vane.3.2.4 distance constant (L, m)the distance the air flowspast a rotating anemometer during the time it takes the cup1This practice is under the jurisdiction ofASTM Committee D22 on Air Qualityand is the direct responsibility
13、of Subcommittee D22.11 on Meteorology.Current edition approved March 15, 2017. Published March 2017. Originallyapproved in 1996. Last previous edition approved in 2011 as D5741 96 (2011).DOI: 10.1520/D5741-96R17.2For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Cus
14、tomer Service at serviceastm.org. For Annual Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.3The boldface numbers in parentheses refers to the list of references at the endof this standard.Copyright ASTM International, 100 Barr Harbor Drive,
15、 PO Box C700, West Conshohocken, PA 19428-2959. United StatesThis international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for theDevelopment of International Standards, Guides and Recommendations issue
16、d by the World Trade Organization Technical Barriers to Trade (TBT) Committee.1wheel or propeller to reach (1 1e) or 63 % of the equilibriumspeed after a step change in wind speed. See Test MethodD5096.3.2.5 maximum operating speed (um, m/s)as related toanemometer, the highest speed as which the sen
17、sor will survivethe force of the wind and perform within the accuracyspecification.3.2.6 maximum operating speed (um, m/s)as related towind vane, the highest speed at which the sensor will survivethe force of the wind and perform within the accuracyspecification.3.2.7 standard deviation of wind dire
18、ction (, degrees)the unbiased estimate of the standard deviation of winddirection samples about the mean horizontal wind direction.The circular scale of wind direction with a discontinuity atnorth may bias the calculation when the direction oscillatesabout north. Estimates of the standard deviation
19、such assuggested by (2, 3) are acceptable.3.2.8 standard deviation of wind speed (u, m/s)the esti-mate of the standard deviation of wind speed samples about themean wind speed.3.2.9 starting threshold (u0, m/s)as related toanemometer, the lowest speed at which the sensor begins toturn and continues
20、to turn and produces a measurable signalwhen mounted in its normal position (see Test Method D5096).3.2.10 starting threshold (u0, m/s)as related to system, theindicated wind speed when the anemometer is at rest.3.2.11 starting threshold (u0, m/s)as related to wind vane,the lowest speed at which the
21、 vane can be observed ormeasured moving from a 10 offset position in a wind tunnel(see Test Method D5366).3.2.12 wind direction (, degrees)the direction, referencedto true north, from which air flows past the sensor location ifthe sensor or other obstructions were absent. The wind direc-tion distrib
22、ution is characterized over each 10-min period witha scalar (non-speed weighted) mean, standard deviation, andthe direction of the peak 1-min average speed. The circulardirection range, with its discontinuity at north, requires specialattention in the averaging process. A unit vector method is anacc
23、eptable solution to this problem.3.2.12.1 DiscussionWind vane direction systems provideoutputs when the wind speed is below the starting threshold forthe vane. For this practice, report the calculated values (see 4.3or 4.4) when more than 25 % of the possible samples are abovethe wind vane threshold
24、 and the standard deviation of theacceptable samples, , is 30 or less, otherwise report lightand variable code, 000.3.2.13 wind speed (u, m/s)the speed with which air flowspast the sensor location if the sensor or other obstructions wereabsent. The wind speed distribution is characterized over each1
25、0-min period with a scalar mean, standard deviation, peak 3-saverage, and peak 1-min average.4. Summary of Practice4.1 Siting of the Wind Sensors:4.1.1 The wind sensor location will be identified by anunambiguous label which will include either the longitude andlatitude with a resolution of1sofarc(a
26、bout 30 m or less) ora station number which will lead to that information in thestation description file. When redundant sensors or microscalenetwork stations (for example, airport runway sensors) areavailable, they will have individual labels which unambigu-ously identify the data they produce.4.1.
27、2 The anemometer and wind vane shall be located at a10-m height above level or gently sloping terrain with an openfetch of at least 150 m in all directions, with the largest fetchpossible in the prevailing wind direction. Compromise isfrequently recognized and acceptable for some sites. Obstaclesin
28、the vicinity should be at least ten times their own heightdistant from the wind sensors.4.1.3 The wind sensors shall preferably be located on top ofa solitary mast. If side mounting is necessary, the boom lengthshould be at least three times the mast width. In the undesirablecase that locally no ope
29、n terrain is available and the measure-ment is to be made above some building, then the wind sensorheight above the roof top should be at least 1.5 times the lesserof the maximum building height and the maximum horizontaldimension of the major roof surface. In this case, the stationdescription file
30、shall indicate the height above ground level(AGL) of the highest part of the building, the height of thewind sensors above ground, AGL, and the height of the windsensors above roof level. Site characteristics shall be docu-mented in sectors no greater than 45 degrees nor smaller than30 degrees in wi
31、dth around the wind sensors. The near terrainmay be characterized with photographs, taken at wind sensorheight if possible, aimed radially outward at labeled centralangles, with respect to true north. Average roughness of thenearest 3 km of each sector shall be characterized according tothe roughnes
32、s class as tabulated above (4). The z0numbers inTable 1 are typical and not precise statements.4.1.4 Important terrain features at distances larger than 3 km(hills, cities, lakes, and so forth, within 20 km) shall beidentified by sector and distance. Additional information, suchas aerial photographs
33、, maps, and so forth, pertinent to the site,is recommended to be added to the basic site documentation.NOTE 2Cameras using 35-mm film in the landscape orientation willhave the following theoretical focal length to field angle relationships:50 mm yields 4040 mm yields 4828 mm yields 66Prints or trans
34、parencies may not utilize the total theoretical width of theimage. It is desirable to label known angles in the photograph. Forexample, a 45 sector photograph could have a central label of 360 withmarker flags located at 337.5 and 022.5 true.4.2 Characteristics of the Wind SystemsThere are twocatego
35、ries of sensor design within this practice. Sensitivedescribes sensors commonly applied for all but extreme windconditions. Ruggedized describes sensors intended to functionduring extreme wind conditions. The application of this prac-tice requires the starting threshold (u0) of both the wind vaneand
36、 the anemometer to meet the same operating range cat-egory.D5741 96 (2017)24.2.1 Operating Range:Category Starting Threshold, u0Maximum Speed, umSensitive 0.5 m/s 50 m/sRuggedized 1.0 m/s 90 m/s4.2.2 Dynamic Response CharacteristicsDynamic re-sponse characteristics of the measurement system may incl
37、udeboth the sensor response and a measurement circuit contribu-tion. The specified values are for the entire measurementsystem, including sensors and signal conditioners (5).Itisexpected that the characteristics of the sensors, which can beindependently determined by the referenced Test MethodsD5096
38、 and D5366, will not be measurably altered by thecircuitry.Anemometer Distance constant, L 0.3Wind vane Damped natural wavelength, d10 m/s 5 % of readingWind direction Degrees of arc to true north 5 (see Note 5)NOTE 3The relative accuracy of the position of the vane with respectto the sensor base sh
39、ould be less than 63 for averaged samples. The biasof the sensor base alignment to true north should be less than 62.4.2.4 Measurement Resolution:Average StandardDeviationWind speed 0.1 m/s 0.1 m/sWind direction 1 0.14.2.5 SamplingPeriods of time, specified as the averagingintervals, are fixed clock
40、 periods and not running or overlap-ping intervals, except for the three-second gust. Outputs mustbe continuously and uniformly sampled during the reportingperiod. Incomplete data must be identified.Wind speed 1 to3s(seeNote 4)Winddirection 1to3s(seeNote 5)NOTE 4A true 3-s average wind speed results
41、 from counting theoutput pulses of the anemometer transducer for 3 s. If a pulse-generatingtransducer is not used, a suitable sampling rate and averaging method isrequired to produce a true 3-s average.NOTE 5A sample of the wind direction may be used ONLY when thesample of wind speed is at or above
42、the wind direction starting threshold.4.3 Standard Data Output for ArchivesTime labels shoulduse the ending time of the interval. If a different labelingmethod is consistently used, it must be defined. The dataoutputs are listed as follows:4.3.1 Ten-minute scalar averaged wind speed.4.3.2 Ten-minute
43、 unit vector or scalar averaged wind direc-tion.4.3.3 Fastest 3-s gust during the 10-min period.4.3.4 Time of the fastest 3-s gust during the 10-min period.4.3.5 Fastest 1-min scalar averaged wind speed during the10-min period (fastest minute).4.3.6 Average wind direction for the fastest 1-min winds
44、peed.4.3.7 Standard deviation of the wind speed samples (1 to 3s) about the 10-min mean speed (u).4.3.8 Standard deviation of the wind direction samples (1 to3 s) about the 10-min mean direction ().4.4 Optional Condensed Data Output for ArchivesSomenetworks will not be able to save eight 10-min data
45、 sets (48values plus time and identification) each hour. For those cases,an abbreviated or condensed alternative is provided. When thecondensed output is employed the following outputs arerequired.4.4.1 Sixty-minute scalar averaged wind speed.4.4.2 Sixty-minute unit vector or scalar averaged winddir
46、ection.4.4.3 Fastest 3-s gust during the 60-min period.4.4.4 Wind direction for the fastest 3-s gust.4.4.5 Fastest 1-min scalar averaged wind speed during the60-min period.4.4.6 Average wind direction for the fastest 1-min windspeed.4.4.7 Ending time of the fastest 1-min wind speed.4.4.8 Root-mean-s
47、quare of six 10-min standard deviationsof the wind speed samples about their 10-min mean speeds.4.4.9 Root-mean-square of six 10-min standard deviationsof the wind direction samples about their 10-min meandirections.4.5 Nonstandard Data Outputs for ArchivesWhen some,but not all, of the required outp
48、uts are reported from a stationwhich meets all of the measurement and sensor performancespecifications, they may be reported as conforming to thestandard with missing data. Stations which report all theTABLE 1 Characterizations Extracted from Wieringa, J. (4)No. z0, m Landscape Description1: 0.0002
49、Sea Open sea or lake (irrespective of the wave size), tidal flat, snow-covered flat plain, featureless desert, tarmac and concrete, with afree fetch of several kilometres.2: 0.005 Smooth Featureless land surface without any noticeable obstacles and with negligible vegetation; for example, beaches, pack ice withoutlarge ridges, morass, and snow-covered or fallow open country.3: 0.03 Open Level country with low vegetation (for example, grass) and isolated obstacles with separations of at least 50 obstacle heights; forexample, gra