EEZ PSU consolidated r5B12

Ministero della SaluteDIPARTIMENTO PER LA SANITÀ PUBBLICA VETERINARIA, LANUTRIZIONE E LA SICUREZZA DEGLI ALIMENTIDIREZIONE GENERALE DELLA SICUREZZA DEGLI ALIMENTI E DELLANUTRIZIONEDECRETOProdotti fitosanitari: recepimento della direttiva 2006/62/CE della Commissione del 12 luglio 2006, della direttiva 2007/55/CE della Commissione del 17 settembre 2007, della direttiva 2007/62/CE della Commissione del 4 ottobre 2007 e aggiornamento del decreto del Ministro della salute 27 agosto 2004 concernente i limiti massimi di residui delle sostanze attive nei prodotti destinati all’alimentazione. Sedicesima modifica.IL MINISTRO DELLA SALUTEVisti gli articoli 5, lettera h), e 6, della legge 30 aprile 1962, n. 283, successivamente modificata con legge 26 febbraio 1963, n. 441;Visto l'articolo 19 del decreto legislativo 17 marzo 1995, n. 194, che prevede l'adozione con decreto del Ministro della salute di limiti massimi di residui di sostanze attive dei prodotti fitosanitari;Visto l'articolo 34 del decreto del Presidente della Repubblica 23 aprile 2001, n. 290, relativo ai residui ed intervalli di carenza;Visto il decreto del Ministro della salute 27 agosto 2004 “Prodotti fitosanitari: limiti massimi di residui della sostanze attive nei prodotti destinati all’alimentazione” (pubblicato nella Gazzetta Ufficiale – Serie generale n. 292 del 14 dicembre 2004, supplemento ordinario n. 179), modificato dal decreto del Ministro della salute 17 novembre 2004 (pubblicato nella Gazzetta Ufficiale n. 30 del 7 febbraio 2005), dal decreto del Ministro della salute 4 marzo 2005 (pubblicato nella Gazzetta Ufficiale n. 121 del 26 maggio 2005), dal decreto del Ministro della salute 13 maggio 2005 (pubblicato nella Gazzetta Ufficiale n. 184 del 9 agosto 2005), dal decreto del Ministro della salute 15 novembre 2005 (pubblicato nella Gazzetta Ufficiale n. 28 del 3 febbraio 2006), dal decreto del Ministro della salute 19 aprile 2006 (pubblicato nella Gazzetta Ufficiale n. 162 del 14 luglio 2006), dal decreto del Ministro della salute 20 aprile 2006 (pubblicato nella Gazzetta Ufficiale n. 161 del 13 luglio 2006), dal decreto del Ministro della salute 23 giugno 2006 (pubblicato nella Gazzetta Ufficiale n. 204 del 2 settembre 2006), dal decreto del Ministro della salute 3 ottobre 2006 (pubblicato nella Gazzetta Ufficiale n. 282 del 4 dicembre 2006), dal decreto del Ministro della salute 26 febbraio 2007 (pubblicato nella Gazzetta Ufficiale n. 102 del 4 maggio 2007); dal decreto del Ministro della salute 13 giugno 2007 (pubblicato nella Gazzetta Ufficiale n. 199 del 28 agosto 2007); dal decreto del Ministro della salute 13 giugno 2007 (pubblicato nella Gazzetta Ufficiale n. 200 del 29 agosto 2007); dal decreto del Ministro della salute 13 giugno 2007 (pubblicato nellaGazzetta Ufficiale n. 201 del 30 agosto 2007); dal decreto del Ministro della salute 31 luglio 2007 (pubblicato nella Gazzetta Ufficiale n. 253 del 30 ottobre 2007); dal decreto del Ministro della salute 31 luglio 2007 (pubblicato nella Gazzetta Ufficiale n. 254 del 31 ottobre 2007);Vista la direttiva 2006/62/CE della Commissione del 12 luglio 2006, che modifica gli allegati delle direttive 76/895/CEE, 86/362/CEE, 86/363/CEE e 90/642/CEE del Consiglio, per quanto riguarda i limiti massimi di residui delle sostanze attive desmedifam, fenmedifam e clorfenvinfos;Vista la direttiva 2007/55/CE della Commissione del 17 settembre 2007, che modifica l’allegato delle direttive 76/895/CEE, 86/362/CEE, 86/363/CEE e 90/642/CEE del Consiglio, per quanto riguarda i limiti massimi di residui della sostanza attiva azinfos-metile;Vista la direttiva 2007/62/CE della Commissione del 4 ottobre 2007, che modifica l’allegato delle direttive 86/362/CEE e 90/642/CEE del Consiglio, per quanto riguarda i limiti massimi di residui delle sostanze attive bifenazato, petoxamide, pirimetanil e rimsulfuron;Visto il decreto dirigenziale della Direzione Generale della Sicurezza degli Alimenti e della Nutrizione emanato l’8 gennaio 2007, per prodotti fitosanitari contenenti la sostanza attiva azinfos-metile, con il quale sono stati revocate le loro autorizzazioni per la non iscrizione della relativa sostanza attiva nell’allegato I del decreto legislativo 17 marzo 1995, n.194;Vista la necessità di rettificare l’elenco degli impieghi della sostanza attiva cimoxanil nell’allegato 5 del decreto del Ministro della salute 27 agosto 2004 per l’impiego sull’indivia;Visto il parere favorevole della Commissione Consultiva Prodotti Fitosanitari espresso nella seduta plenaria del 16 ottobre 2007 relativamente all’abrogazione dei limiti massimi di residui delle sostanze attive sulla coltura del tabacco, riportati nell’allegato 2 del decreto del Ministro della salute 27 agosto 2004 e successivi aggiornamenti;Ritenuto necessario aggiornare il decreto del Ministro della salute 27 agosto 2004 e successivi aggiornamenti, con i nuovi limiti massimi di residui delle sostanze attive azinfos metile, bifenazato, clorfenvinfos, desmedifam, fenmedifam, petoxamide, pirimetanil e rimsulfuron;Visto il parere favorevole della Commissione Consultiva Prodotti Fitosanitari espresso nella seduta plenaria del 18 dicembre 2007 relativamente alla presente sedicesima modifica del decreto del Ministro della salute 27 agosto 2004;DECRETA:Art. 1Limiti massimi di residui1. I limiti massimi di residui delle sostanze attive azinfos metile, clorfenvinfos, desmedifam, fenmedifam, pirimetanil e rimsulfuron indicati nell’allegato 1 del presente decreto, sostituiscono i corrispondenti limiti massimi di residui indicati nell’allegato 2 del decreto del Ministro della salute 27 agosto 2004 e successivi aggiornamenti.2. I limiti massimi di residui delle sostanze attive bifenazato e petoxamide indicati nell’allegato 1 del presente decreto, sono aggiunti a quelli indicati nell’allegato 2 del decreto del Ministro della salute 27 agosto 2004 e successivi aggiornamenti.3. I limiti massimi di residui delle sostanze attive azinfos-metile e clorfenvinfos, indicati in allegato 2 del presente decreto, sono aggiunti nell’allegato 3, parte A, del decreto del Ministro della salute 27 agosto 2004 e successivi aggiornamenti.4. I limiti massimi di residui della sostanza attiva fenmedifam, indicati in allegato 2 del presente decreto, sono aggiunti nell’allegato 3, parte B, del decreto del Ministro della salute 27 agosto 2004 e successivi aggiornamenti.5. I nuovi limiti massimi di residui, che trovano applicazione per i trattamenti effettuati dopo l’entrata in vigore dei limiti stessi, si applicano per le sostanze attive desmedifam, fenmedifam e clorfenvinfos a decorrere dal 21 gennaio 2008; per la sostanza attiva azinfos-metile a decorrere dal 19 marzo 2008; per le sostanze attive bifenazato, petoxamide, pirimetanil e rimsulfuron a decorrere dal 6 aprile 2008.Art. 2Impieghi e intervalli di sicurezza1. Gli impieghi e gli intervalli di sicurezza relativi alle sostanze attive azinfos-metile e cimoxanil indicati nell’allegato 3 del presente decreto, sostituiscono quelli dell’allegato 5 del decreto del Ministro della salute 27 agosto 2004 e successivi aggiornamenti.Il presente decreto, trasmesso alla Corte dei Conti per la registrazione e pubblicato nella Gazzetta Ufficiale della Repubblica italiana, entrerà in vigore dal giorno successivo alla sua pubblicazione.Roma, 22 gennaio 2008Il MINISTROLivia TurcoALLEGATO 1LIMITI MASSIMI DI RESIDUI DELLE SOSTANZE ATTIVE DEI PRODOTTI FITOSANITARI TOLLERATI NEI PRODOTTI DESTINATI ALL'ALIMENTAZIONE (ESCLUSI I PRODOTTI DI ORIGINE ANIMALE) IN ATTUAZIONE DI DISPOSIZIONI COMUNITARIE (VALORI SOTTOLINEATI), NONCHE’ LIMITI MASSIMI DI RESIDUI PROVVISORI NAZIONALI IN ATTESA DI ARMONIZZAZIONE COMUNITARIA (VALORI NON SOTTOLINEATI).Denominazione sostanza attiva e principale attivitàfitoiatrica Prodotti destinati all’alimentazione LMR inmg/Kg(= ppm)NoteAZINFOS-METILE (insetticida) Frutta a guscio………………………………...Pomacee, drupacee, fragole (escluse le fragoleselvatiche), frutti di piante arbustive (escluse leselvatiche), ribes (rosso, nero e bianco), uva spina………………………………………….Mirtilli rossi………………………………….Altra frutta…………………………………… Cetrioli……………………………………….Altri ortaggi…………………………………..Legumi da granella…………………………..Semi di cotone……………………………….Altri semi oleaginosi………………………… Patate…………………………………………Tè……………………………………………. Luppolo……………………………………… Cereali………………………………………..Barbabietola da zucchero…………………….Erba medica………………………………….0,50,5 t0,10,05*0,20,05*0,05*0,20,05*0,05*0,1*0,1*0,05*0,20,5(t) LMR temporaneo fino al18 settembre 2008. Dopotale data l’LMR sarà di0,05* mg/Kg salvoaltrimenti modificato da unadirettiva o da unregolamento.BIFENAZATO (acaricida) Fragole (escluse le fragole selvatiche)……….Altra frutta……………………………………Pomodori, melanzane………………………… Peperoni………………………………………Cucurbitacee con buccia commestibile………Altri ortaggi…………………………………..Legumi da granella……………………………Semi oleaginosi………………………………. Patate………………………………………….Tè…………………………………………….. Luppolo………………………………………. Cereali………………………………………...20,01*0,520,30,01*0,01*0,02*0,01*0,02*0,02*0,01*La quantità massima diresidui è stata fissataprovvisoriamente a normadell’articolo 4, paragrafo 1,lettera f), della 91/414/CEE.Salvo modifica, tale quantitàmassima diverrà definitiva il25 ottobre 2011.CLORFENVINFOS (insetticida)Frutta…………………………………………Carote, pastinaca, ravanelli, navoni-rutabaga,rape, agli, scalogni, cavoli cappucci,prezzemolo, sedani…………………………..Zucchine, cavoletti di Bruxelles, crescione,dolcetta, spinaci, asparagi, porri……………..Cavoli-rapa…………………………………...Funghi coltivati………………………………Altri ortaggi………………………………….Legumi da granella…………………………..Semi oleaginosi……………………………… Patate…………………………………………Tè……………………………………………..0,02*0,50,10,30,050,02*0,02*0,02*0,02*0,05*Somma degli isomeri E e ZSostanza attiva non ammessanei prodotti fitosanitarifitoiatrica (= ppm)Luppolo………………………………………. Cereali……………………………………….. 0,05* 0,02*DESMEDIFAM (diserbante) Frutta………………………………………… Ortaggi……………………………………….Legumi da granella…………………………..Semi oleaginosi……………………………… Patate………………………………………….Tè…………………………………………….. Luppolo………………………………………. Cereali……………………………………….Barbabietole da zucchero……………………0,05* p0,05* p0,05* p0,1* p0,05* p0,1* p0,1* p0,05* p0,1(p) Indica che la quantità diresidui è stata fissataprovvisoriamente a normadell’articolo 4, paragrafo 1,lettera f), della direttiva91/414/CEEFENMEDIFAM (diserbante) Fragole (escluse le fragole selvatiche)………Altra frutta……………………………………Bietole rosse (o da orto)……………………..Spinaci e simili……………………………… Carciofi………………………………………Altri ortaggi………………………………….Legumi da granella…………………………...Semi oleaginosi……………………………… Patate…………………………………………Tè…………………………………………….. Luppolo……………………………………… Cereali………………………………………...Barbabietole da zucchero…………………….Barbabietole da foraggio……………………..0,1* p0,05* p0,1* p0,5.p0,2.p0,05* p0,05* p0,1* p0,05* p0,1* p0,1* p0,05* p0,10,1(p) Indica che la quantità diresidui è stata fissataprovvisoriamente a normadell’articolo 4, paragrafo 1,lettera f), della direttiva91/414/CEEPETOXAMIDE (erbicida) Frutta………………………………………… Ortaggi………………………………………..Legumi da granella……………………………Semi oleaginosi………………………………. Patate………………………………………….Tè…………………………………………….. Luppolo………………………………………. Cereali………………………………………...0,01*0,01*0,01*0,01*0,01*0,02*0,02*0,01*La quantità massima diresidui è stata fissataprovvisoriamente a normadell’articolo 4, paragrafo 1,lettera f), della 91/414/CEE.Salvo modifica, tale quantitàmassima diverrà definitiva il25 ottobre 2011.PIRIMETANIL (fungicida) Agrumi, pesche (comprese le nettarine e ibridisimili), more, lamponi………………………..Mandorle, pistacchi…………………………..Pomacee, uve da tavola e da vino, fragole(escluse le fragole selvatiche), altra piccolafrutta e bacche (escluse quelle selvatiche)……Albicocche, prugne…………………………... Banane………………………………………...Altra frutta…………………………………….Carote, pomodori, melanzane, cucurbitacee conbuccia commestibile, porri…………………… Cipolle………………………………………...Peperoni, fagioli (con baccello)……………… Lattuga………………………………………..Erbe fresche…………………………………..Piselli (senza baccello)……………………….100,2530,10,05*10,121030,2(p) Indica che la quantitàmassima di residui è statafissata provvisoriamente anorma dell’articolo 4,paragrafo 1, lettera f), delladirettiva 91/414/CEE. Salvomodifica, tale quantitàmassima diverrà definitiva il25 ottobre 2011.fitoiatrica (= ppm)Altri ortaggi…………………………………... Legumi da granella…………………………… Semi oleaginosi………………………………. Patate…………………………………………. Tè…………………………………………….. Luppolo………………………………………. Cereali………………………………………... 0,05* 0,5 0,1* 0,05* 0,1* 0,1* 0,05*RIMSULFURON (diserbante) Frutta…………………………………………. Ortaggi………………………………………..Legumi da granella……………………………Semi oleaginosi………………………………. Patate………………………………………….Tè…………………………………………….. Luppolo………………………………………. Cereali………………………………………...0,05*0,05*0,05*0,05*0,05*0,10,1*0,05*La quantità massima diresidui è stata fissataprovvisoriamente a normadell’articolo 4, paragrafo 1,lettera f), della 91/414/CEE.Salvo modifica, tale quantitàmassima diverrà definitiva il25 ottobre 2011.(*) Indica il limite inferiore di determinazione analitica.ALLEGATO 2 PARTE ALimiti massimi in mg/kg (ppm)Residui di antiparassitari di grassi delle carni, preparazioni a basedi carni, frattaglie e dei grassi animalielencati nell’allegato I alle voci ex 0201,0202, 0203, 0204, 0205 00 00, 0206, 0207,ex 0208, 0209 00, 0210, 1601 00, 1602(1) (4)per il latte di vacca crudo ed il latte divacca intero della voce 0401dell’allegato I; per gli altri prodottialimentari delle voci 0401, 0402, 040500 e 0406 conformemente a(2) (4)di uova fresche in guscio, uova divolatili e tuorli d’uovo elencatinell’allegato I alle voci 0407 00, 0408(3) (4)AZINFOS-METILE 0,01* 0,01* 0,01*CLORFENVINFOS(somma degli isomeri E e Z)0,01* 0,01* 0,01* p(*) Indica il limite inferiore di determinazione analitica.7ALLEGATO 2 PARTE BLimiti massimi in mg/kg (ppm)Residui di antiparassitari di carni, inclusi i grassi, preparazioni abase di carne, frattaglie e grassi animalielencati nell’allegato I, di cui alle voci ex0201, 0202, 0203, 0204, 0205 00 00, 0206,0207, ex 0208, 0209 00, 0210, 1601 00,1602per il latte e i prodotti lattiero-casearidell’allegato I; di cui ai codici 0401,0402, 0405 00 e 0406di uova fresche in guscio, di uova divolatili e tuorli d’uovo elencatinell’allegato I, alle voci 0407 00, 0408FENMEDIFAM [metil-N-(3-idrossifenil) carbammato (MHPC)espresso in fenmedifam0,05* p 0,05* p 0,05* p(*) Indica il limite inferiore di determinazione analitica.(p) Indica che la quantità massima di residui è stata fissata provvisoriamente a norma dell’articolo 4, paragrafo 1, lettera f), della direttiva 91/414/CEE. Salvo modifica, tale quantità massima diverrà definitiva il 9 agosto 2010.8ALLEGATO 3 IMPIEGHI AUTORIZZATI IN ITALIA E INTERVALLI DI SICUREZZA CHE DEVONO INTERCORRERE TRA L’ULTIMO TRATTAMENTO(1) E LA RACCOLTA E, PER LE DERRATE ALIMENTARI IMMAGAZZINATE, TRA L’ULTIMO TRATTAMENTOE L’IMMISSIONE IN CIRCOLAZIONE.(1) Salvo diversa indicazione i trattamenti si intendono effettuati alla colturaDenominazione sostanza attiva e principale azionefitoiatrica Colture Intervallo ingg.Derrate alimentariimmagazzinateIntervallo ingg.AltriimpieghiNoteAZINFOS-METILE (insetticida) Impieghi ammessi fino al 31.12.2007Agrumi, mandorlo, nocciolo, pomacee,drupacee, vite, fragola, olivo…………….......Ortaggi a radice e tubero, solanacee, cetriolo,zucca, cavoli, lattughe e simili, spinaci e simili,erbe fresche, legumi, asparago, cardo, sedano,finocchio, carciofo………………....................Soia, colza…………….................................... Patata……………............................................Frumento, mais…………….............................Barbabietola da zucchero……………..............Erba medica…………….................................. Tabacco…………….........................................Floreali, ornamentali, forestali, pioppo……….202020202020202020Applicazionein vivaio sullecoltureautorizzate incampo.Sostanza attiva noniscritta nell’allegatoI del DL 17 marzo1995, n. 194(Regolamento CE n.1335/2005 dellaCommissione del12.08.2005)Applicazione allacoltura e al terreno.CIMOXANIL (fungicida) Vite…………….......................................…….Aglio, cipolla, pomodoro(1), cetriolo, zucchino,melone, lattuga, indivia, spinacio, pisello, porro.................................................................. Carciofo…………….................................……Girasole, soia…………….........................…… Patata……………....................................……. Tabacco…………….................................…… Rosa……………......................................…….101021281010---Impiego sufloreali eornamentalidaappartamentoe da giardinodomestico.(1) Ancheapplicazione inserra9。

at BPS4000 rev(yy/mm/dd)SupersedingDoc160-006AM040322BHTI Alternate Materials List M&P 299-947-100-690115BHTI Procurement Specification for Epoxy Adhesive, Heat Resistant M&P 299-947-320-820507BHTI Adhesive Film and Primer System, Intermediate CureTemperature (260-290º F) Service Temperature 67-225º F)M&P 68A900000G011101BAC Finish Spec: F-15M&P 74A900000E990308BAC Finish Specification for F18 Aircraft M&P 74A900004DG M051220BAC Ctrl: Fract Crit Parts, F-18M&P 74A901001F981208BAC Std Finish Codes: F-18 A\C M&P 901-947-002CA D950510BHTI Finish Specification for the V-22 Aircraft (Bell Boeing) Model901) EMD AircraftM&P A-A-208See Special Notes DL C120719FED Ink, Marking, Stencil, Opaque Use A-A-00208 in lieu of A-A-208.M&P A-A-2962Cancelled - no s/s spec A980810Cancel Notice 2FED Commercial Item Description Enamel, Alkyd, Exterior, SolventBased, Low VocOk to use canc spec.M&P A-A-3097DC-970506Notice 4FED Commercial Item Description Adhesives, Cyanoacrylate, RapidRoom Temperature-Curing, SolventlessM&P A-A-3165DE A071116FED Lacquer, Gloss, for A/C Use M&P A-A-00208See Special Notes DL D121001FED Commercial Item Description Ink, Marking, Stencil, Opaque(Porous and Non-Porous Surfaces)Use A-A-00208 in lieu of A-A-208.M&P A-A-52080B980523Notice 1FED Tape, Lacing, and Tying, Nylon M&P A-A-52081DF B980523Notice 1FED Tape, Lacing, and Tying, Polyester M&P A-A-52082DC D090817FED Tape, Lacing and Tying, TFE-Fluorocarbon M&P A-A-52083BJ C040223FED Tape, Lacing, and Tying, Glass M&P A-A-52084B980523Notice 1FED Tape, Lacing and Tying, Aramid M&P A-A-55829DC A110322DLA Acetic Acid, Glacial, Technical M&P A-A-56032CN D030521Notice 1FED Commercial Item Description (CIDS) Ink, Marking, Epoxy Base M&P A-A-59126-970926FED Terminals, Feedthru (Insulated) and Terminals, Stud (Insulatedand Noninsulated)ENG A-A-59132CR A100607Validation Notice 1DLA Amyl Acetate, Technical M&P A-A-59135CR-971028FED Commercial Item Description Packaging Material, Sheet M&P A-A-59136CR-971028FED Cushioning Material, Packaging, Closed Cell Foam Plank M&PA-A-59178DD A041012Notice 1USGOVT Nipple, Electrical Terminal ENGA-A-59503DC C110303FED Commercial Item Description Nitrogen, Technical M&PA-A-59551CP A091022USGOVT Wire, Electrical, Copper (Uninsulated) M&PA-A-59569DJ C090122Notice 1DLA Qualification Sampling and Testing of Steels for TransverseTensile PropertiesENG A-A-59588DJ B120130Notice 1FED Commercial Item Description Rubber, Silicone M&P A-A-59877CT-100909FED Commercial Item Description Insulating Compound, Electrical,EmbeddingM&P AIR4127CG - 071101SAE Steel: Chemical Composition and Hardenability M&P AISI-1010Unavailable-AISI Low Carb Stl Unavailable M&P AISI-50100Unavailable-AISI Bearing Stl Unavailable M&P AISI-52100Unavailable-AISI Bearing Stl Unavailable M&P AISI-B-1112Unavailable-AISI Low Carb Free Mach Stl Unavailable M&P AISI-C-1212Unavailable-AISI Material Spec, Stl Unavailable M&P AISI-C-1213Unavailable-AISI Low Carb Free Mach Stl Unavailable M&P AISI-C-1214Unavailable-AISI Material Spec, Stl Unavailable M&P AMS 2175CR A100601SAE Castings, Classification and Inspection of M&P AMS 2201Cancelled CN Can940901SAE Tolerances Aluminum and Aluminum Alloy Bar, Rod, Wire, andForging Stock Rolled or Cold-FinishedANSI H35.2M&P AMS 2221G060201SAE Tolerances, Copper and Copper Alloy Bars and Rods M&P AMS 2222BG J060201SAE Tolerances, Copper and Copper Alloy Sheet, Strip, and Plate M&Pat BPS4000 rev(yy/mm/dd)SupersedingDocAMS 2223BF H060201SAE Tolerances Copper and Copper Alloy Seamless Tubing M&P AMS 2224G060201SAE Tolerances Copper and Copper Alloy Wire M&P AMS 2241CN R070701SAE Tolerances, Corrosion and Heat-Resistant Steel, Iron Alloy,M&PTitanium, and Titanium Alloy Bars and WireM&P AMS 2242CC G080604SAE Tolerances Corrosion and Heat Resistant Steel, Iron Alloy,Titanium and Titanium Alloy Sheet, Strip and PlateAMS 2243DH K130601SAE Tolerances Corrosion and Heat-Resistant Steel Tubing M&PM&P AMS 2248DB G110301SAE Chemical Check Analysis Limits Corrosion and Heat-ResistantSteels and Alloys, Maraging and other Highly-Alloyed Steels,and Iron AlloysAMS 2249CN G090701SAE Chemical Check Analysis Limits Titanium and Titanium Alloys M&PM&P AMS 2259CN E071201SAE Chemical Check Analysis Limits Wrought Low-Alloy andCarbon SteelsAMS 2269CN F060501SAE Chemical Check Analysis Limits Nickel, Nickel Alloys, andM&PCobalt AlloysM&P AMS 2300CU L100801SAE Steel Cleanliness, Premium Aircraft-Quality Magnetic ParticleInspection ProcedureM&P AMS 2301CT K100801SAE Steel Cleanliness, Aircraft Quality Magnetic Particle InspectionProcedureAMS 2303CT F100801SAE Steel Cleanliness, Aircraft Quality, Martensitic CorrosionM&PResistant Steels Magnetic Particle Inspection ProcedureM&P AMS 2304CV B100801SAE Steel Cleanliness, Special Aircraft-Quality Magnetic ParticleInspection ProcedureM&P AMS 2310BE F060201SAE Qualification Sampling and Testing of Steels for TransverseTensile PropertiesAMS 2315DF G130201SAE Determination of Delta Ferrite Content M&P AMS 2350Cancelled - no s/s spec CN BA891001SAE Standards and Test Methods Ok to use canc spec.M&PM&P AMS 2355DB K110301SAE Quality Assurance Sampling and Testing Aluminum Alloys andMagnesium Alloy Wrought Products (Except Forging Stock),and Rolled, Forged, or Flash Welding RingsAMS 2360CN D070701SAE Room Temperature Tensile Properties of Castings M&PM&P AMS 2370DB K110601SAE Quality Assurance Sampling and Testing Carbon and Low-AlloySteel Wrought Products and Forging StockAMS 2371DB J110601SAE Quality Assurance Sampling and Testing Corrosion and Heat-M&PResistant Steels and Alloys Wrought Products and ForgingStockM&P AMS 2372DB F110601SAE Quality Assurance Sampling and Testing Carbon and Low-AlloySteel ForgingsAMS 2375CN D070601SAE Control of Forgings Requiring First Article Approval M&P AMS 2380CN F080601SAE Approval and Control of Premium-Quality Titanium Alloys M&P AMS 2400DG X130201SAE Plating, Cadmium M&P AMS 2401DF J130201SAE Plating, Cadmium Low Hydrogen Content Deposit M&P AMS 2403BM L041001SAE Plating, Nickel General Purpose M&P AMS 2404CH F081201SAE Plating, Electroless Nickel M&P AMS 2405DL E131001SAE Electroless Nickel Plate, Low Phosphorous M&P AMS 2406DE M121101SAE Plating, Chromium Hard Deposit M&P AMS 2408DL K130901SAE Plating, Tin M&P AMS 2410CR K100401SAE Plating, Silver Nickel Strike, High Bake M&P AMS 2411DM H131201SAE Plating, Silver for High Temperature Applications M&P AMS 2412CN J091201SAE Plating, Silver Copper Strike, Low Bake M&P AMS 2416CU L101201SAE Plating, Nickel-Cadmium Diffused M&P AMS 2417DL J130901SAE Plating, Zinc-Nickel Alloy M&P AMS 2418CU H110201SAE Plating, Copper M&P AMS 2419BM C030501SAE Plating, Cadmium-Titanium M&PM&P AMS 2420D021201SAE Plating of Aluminum for Solderability Zinc Immersion Pre-Treatment Processat BPS4000 rev(yy/mm/dd)SupersedingDocAMS 2423See Special Notes CE D020401SAE Plating, Nickel Hard Deposit Continue to use AMS-QQ-N-290 for Class 2Nickel.M&P AMS 2424CR F100401SAE NI Plate, Low Stressed Deposit M&P AMS 2426DL E130901SAE Coating, Cadmium Vacuum Deposition M&P AMS 2427DD D070701SAE Aluminum Coating Ion Vapor Deposition M&P AMS 2429CY D111001SAE Bronze Plate Masking M&P AMS 2430DB S120701SAE Shot Peening, Automatic M&P AMS 2432DF D130201SAE Shot Peening, Computer Monitored M&P AMS 2433C041001SAE Plating, Nickel-Thallium-Boron or Nickel-Boron M&P AMS 2434CY D110901SAE Plating, Tin-Zinc Alloy M&P AMS 2435Noncurrent CN G070601SAE Coating, Tungsten Carbide-Cobalt Coating, Detonation Process M&P AMS 2437BN C710111SAE Coating, Plasma Spray Deposition M&P AMS 2438CL D090701SAE Plating, Chromium Thin, Hard, Dense Deposit M&P AMS 2444BM A001201SAE Coating, Titanium Nitride Physical Vapor Deposition M&P AMS 2451CW C110701SAE Plating, Brush General Requirements M&PAMS 2460See Special Notes DF A130301SAE Plating, Chromium If dwg requires chrome plate per AMS-QQ-C-320then stress relief and embritlmnt (emb) bake reliefper BPS4620. If dwg req's chrome plate per AMS2460then stress relief and bake relief per AMS M&PAMS 2468Cancelled CN G981001SAE Hard Anodic Coating Treatment of Aluminum Alloys AMS 2469M&P AMS 2469DM J140201SAE Hard Anodic Coating Treatment of Aluminum and AluminumAlloys Processing and Performance RequirementsM&P AMS 2470DH N130701SAE Anodic Treatment of Aluminum Alloys Chromic Acid Process M&P AMS 2471DM H140201SAE Anodic Treatment of Aluminum Alloys Sulfuric Acid Process,Undyed CoatingM&P AMS 2472DD F070801SAE Anodic Treatment of Aluminum Alloys Sulfuric Acid Process,Dyed CoatingM&P AMS 2473DK H130801SAE Chemical Film Treatment for Aluminum Alloys General PurposeCoatingM&P AMS 2474Noncurrent DD D060201SAE Chemical Treatment for Aluminum Alloys Low ElectricalResistance CoatingAMS 2477M&P AMS 2477DD A100401SAE Conversion Coating for Aluminum Alloys Low Electrical Coating M&P AMS 2481CP J100201SAE Phosphate Treatment Antichafing M&P AMS 2482CN D100101SAE Hard Anodic Coating on Aluminum AlloysPolytetrafluoroethylene (PTFE)-Impregnated or CodepositedM&P AMS 2485BY K080101SAE Coating, Black Oxide M&P AMS 2486CR E100501SAE Conversion Coating of Titanium Alloys Fluoride-PhosphateTypeM&P AMS 2487CN A000301SAE Anodic Treatment of Titanium and Titanium Alloys Solution pH12.4 MaximumM&P AMS 2488D000606SAE Anodic Tr: Ti, Ti Alys M&P AMS 2515DE G130101SAE Polytetrafluoroethylene (PTFE) Resin Coating Low Build, 370 to400 °C (698 to 752 °F) FusionM&P AMS 2516DF E130301SAE Polytetrafluoroethylene (PTFE) Resin Coating High Build, 370to 400 °C (698 to 752 °F) FusionM&P AMS 2525DJ D130701SAE Graphite Coating, Thin Lubricating Film Impingement Applied M&P AMS 2526DE D130101SAE Molybdenum Disulfide Coating, Thin Lubricating FilmImpingement AppliedM&P AMS 2590DD-101201SAE Rotary Flap Peening of Metal Parts M&P AMS 2615BM F060901SAE Pressure Testing Hydraulic Pressure as Specified M&P AMS 2630CR C100101SAE Inspection, Ultrasonic Product Over 0.5 Inch (12.7 mm) Thick M&P AMS 2631CW D110701SAE Ultrasonic Inspection Titanium and Titanium Alloy Bar and Billet M&P AMS 2632BN A950301SAE Inspection, Ultrasonic, of Thin Materials 0.50 Inch (12.7 mm)and Under in Cross-Sectional ThicknessM&P AMS 2635Cancelled Can810701SAE Radiographic Insp ASTM E1742M&Pat BPS4000 rev(yy/mm/dd)SupersedingDocAMS 2640Cancelled CH Can960401SAE Magnetic Particle Inspection ASTM E1444M&P AMS 2645Cancelled CH Can950201SAE Fluorescent Penetrant Inspection ASTM E1417M&P AMS 2649DM D131201SAE Etch Inspection of High Strength Steel Parts M&P AMS 2658CN C091001SAE Hardness and Conductivity Inspection of Wrought AluminumAlloy PartsM&P AMS 2664CH F950701SAE Brazing, Silver for Use Up to 800 °F (427 °C)M&P AMS 2665DH H130501SAE Brazing, Silver for Use up to 400 °F (204 °C)M&P AMS 2666Cancelled Can840101SAE Ag Braz, High Temp AMS 2664M&P AMS 2670BK J060601SAE Brazing, Copper M&P AMS 2671Cancelled CH Can920101SAE Copper Brazing Corrosion and Heat Resistant Steels andAlloysAMS 2670M&P AMS 2672CY G120101SAE Brazing, Aluminum Torch or Furnace M&P AMS 2673DB E120101SAE Brazing, Aluminum and Aluminum Alloys Molten Flux (Dip)M&P AMS 2675DF H130201SAE Brazing, Nickel Alloy Filler Metal M&P AMS 2680C010601SAE Electron-Beam Welding for Fatigue Critical Applications M&P AMS 2681B000301SAE Electron Beam Welding M&P AMS 2685Noncurrent CP E071001SAE Welding, Tungsten Arc, Inert Gas GTAW Method M&P AMS 2689Noncurrent CH A980201SAE Fusion Welding Titanium and Titanium Alloys M&P AMS 2694DE C130101SAE In-Process Welding of Castings M&P AMS 2700DA E111101SAE Passivation of Corrosion Resistant Steels All acceptance testing shall be per Class 4except for Martensitic CRES alloy 440C,which requires no class testing.M&PAMS 2728DC C120901SAE Heat Treatment of Wrought Copper Beryllium Alloy Parts M&P AMS 2745CJ A071201SAE Induction Hardening of Steel Parts M&P AMS 2750DB E120701SAE Pyrometry M&P AMS 2753CF C080801SAE Liquid Salt Bath Ferritic Nitrocarburizing Non-Cyanide Bath M&P AMS 2755Cancelled CM Can090701SAE Nitriding, Molten Salt Bath Process not available, consider AMS 2753 asreplacement.M&P AMS 2759CE E081001SAE Heat Treatment of Steel Parts General Requirements M&PAMS 2759/1CJ E090201SAE Heat Treatment of Carbon and Low-Alloy Steel Parts MinimumTensile Strength Below 220 ksi (1517 MPa)Supersedes MIL-H-6875 for carbon & low-alloy steels below 220 ksi.M&PAMS 2759/2CR F100501SAE Heat Treatment of Low-Alloy Steel Parts Minimum TensileStrength 220 ksi (1517 MPa) and Higher Supersedes MIL-H-6875 for low-alloy steels,220 ksi & higher.M&PAMS 2759/3CE E080801SAE Heat Treatment Precipitation-Hardening Corrosion-Resistantand Maraging Steel Parts Supersedes MIL-H-6875 for precipitationhardening & maraging steel.M&PAMS 2759/4CA C080301SAE Heat Treatment Austenitic Corrosion-Resistant Steel Parts Supersedes MIL-H-6875 for austentic steels.M&P AMS 2759/5D040601SAE Heat Treatment Martensitic Corrosion Resistant Steel Parts Supersedes MIL-H-6875 for martensiticsteels.M&P AMS 2759/6BM B051101SAE Gas Nitriding and Heat Treatment of Low - Alloy Steel Parts Use Standard Drawing Notes per BDS2240.M&P AMS 2759/7CT B100501SAE Carburizing and Heat Treatment of Carburizing Grade SteelPartsM&PAMS 2759/8CG A070601See Special Notes SAE Ion Nitriding 1. Infrared pyrometry may be used to measuretemperature. 2. The nitriding temperature may beless than 50 degrees below the tempering or agingtemperature provided that the core hardness is notreduced. 3. for small loads, a minimum of twot t ti i b d i li M&PAMS 2759/9CL D090501SAE Hydrogen Embrittlement Relief (Baking of Steel Parts)Supersedes MIL-H-6875 for stress relievingsteels.M&P AMS 2759/10CN A060601SAE Automated Gaseous Nitriding Controlled by Nitriding Potential M&P AMS 2759/11BW-050401SAE Stress Relief of Steel Parts M&P AMS 2762Noncurrent CP B020101SAE Carburizing Carbon and Low-Alloy Steel Parts M&P AMS 2768CR C100701SAE Heat Treatment of Magnesium Alloy Castings M&P AMS 2769DD B091201SAE Heat Treatment of Parts in a Vacuum M&P AMS 2770DM L140501SAE Heat Treatment of Wrought Aluminum Alloy Parts M&Pat BPS4000 rev(yy/mm/dd)SupersedingDocAMS 2771DF E130201SAE Heat Treatment of Aluminum Alloy Castings M&P AMS 2772CW F110701SAE Heat Treatment of Aluminum Alloy Raw Materials M&P AMS 2774DC D121001SAE Heat Treatment Wrought Nickel Alloy and Cobalt Alloy Parts M&P AMS 2800CN D060801SAE Identification Finished Parts M&P AMS 2801B030301SAE Heat Treatment of Titanium Alloy Parts M&PM&P AMS 2807CF B080201SAE Identification Carbon and Low-Alloy Steels, Corrosion and Heat-Resistant Steels and Alloys Sheet, Strip, Plate and AircraftTubingAMS 3025CN C090901SAE Polyalkylene Glycol Heat Treat Quenchant M&P AMS 3106Cancelled Can830401SAE Primer, Adhesive, Corr Inhib AMS 3107M&P AMS 3107A910401SAE Primer, Adhesive, Corr-Inhibiting M&P AMS 3195CV F110501SAE Silicone Rubber Sponge, Closed Cell, Medium M&PM&P AMS 3216G050901SAE Fluorocarbon (FKM) Rubber High-Temperature - FluidResistant Low Compression Set 70 to 80AMS 3218C050901SAE Fluorocarbon (FKM) Rubber High-Temperature - FluidM&PResistant Low Compression Set 85 to 95M&P AMS 3276CB E080301SAE Sealing Compound, Integral Fuel Tanks and General Purpose,Intermittent Use to 360 °F (182 °C)AMS 3301DB H110601SAE Silicone Rubber, General Purpose, 40 Durometer M&P AMS 3305H900401SAE Silicone Rubber, Gen Purp, 75-85M&P AMS 3374DL D131101SAE Sealing Compound Aircraft Firewall, Silicone M&P AMS 3410J981001SAE Flux, Ag Braz M&P AMS 3411D981001SAE Flux Silver Brz, High Temp M&PM&P AMS 3644BL G060901SAE Plastic: Polyimide for Molded Rod, Bar, and Tube, Plaque, andformed PartsM&P AMS 3645CY D120101SAE Polychlorotrifluoroethylene (PCTFE), Compression MoldedHeavy Sections, UnplasticizedM&P AMS 3650CY D120101SAE Rods, Sheets, and Molded Shapes, Polychlorotrifluoroethylene(PCTFE) UnplasticizedAMS 3651Cancelled Can870401SAE PTFE AMS 3667M&P AMS 3651Cancelled Can870401PTFE AMS 3652M&P AMS 3651Cancelled Can870401PTFE AMS 3656M&P AMS 3651Cancelled Can870401PTFE AMS 3660M&P AMS 3652C930101SAE PTFE Film, Non-Crit Grade M&P AMS 3656CW H110801SAE PTFE Extrusions, Normal Strength, As Sintered M&P AMS 3657CW F110801SAE PTFE, Extrusions, Premium Strength, As Sintered M&P AMS 3658CW F110801SAE PTFE, Extrusions, Premium M&P AMS 3659CW F110801SAE Polytetrafluoroethylene (PTFE) Extrusions, Premium Strength,M&PSintered and Stress-RelievedAMS 3660CW E110801SAE Polytetrafluoroethylene Moldings M&P AMS 3666DB E120101SAE PTFE Sht, Glass Reinforced M&PM&P AMS 3667CW E110801SAE Polytetrafluoroethylene Sheet, Molded General Purpose Grade,As SinteredAMS 3668CW E110801SAE PTFE, Moldings, Premium Grade, A Sintered M&P AMS 3670/1B950401SAE Unfilled Polyamide-Imide, Bar M&P AMS 3824CN C950901SAE Cloth, Glass Finished for Resin Laminates M&P AMS 4001Cancelled CK Can070701SAE Aluminum Sheet and Plate 0.12Cu (1100-0) Annealed ASTM B209M&P AMS 4013DM G140201SAE Aluminum Sheet, Laminated Surface Bonded M&PM&P AMS 4015CN L070201SAE Aluminum Alloy, Sheet and Plate 2.5Mg - 0.25Cr (5052-0)AnnealedM&P AMS 4016DE M130101SAE Aluminum Alloy, Sheet and Plate 2.5Mg - 0.25Cr (5052-H32)Strain Hardened, Quarter Hard, and Stabilizedat BPS4000 rev(yy/mm/dd)SupersedingDocAMS 4017CN K041201SAE Aluminum Alloy Sheet and Plate 2.5Mg - 0.25Cr (5052-H34)M&PStrain-Hardened, Half Hard, and StabilizedM&P AMS 4023Noncurrent CN E840401SAE Aluminum Alloy Sheet and Plate Alclad 1.0Mg - 0.60Si - 0.28Cu- 0.20Cr (Alclad 6061; -T6 Sheet, -T651 Plate)AMS 4025CE L080701SAE Aluminum Alloy, Sheet and Plate 1.0Mg - 0.60Si-0.28Cu-AMS-QQ-A-250/11A - cancelled - 2008M&P0.20Cr(6061-0) AnnealedAMS-QQ-A-250/11A - cancelled - 2008M&P AMS 4026CE M080701SAE Aluminum Alloy, Sheet and Plate 1.0Mg -0.60Si-0.28Cu-0.20Cr(6061;-T4 Sheet, T-451 Plate) Solution Heat Treated andNaturally AgedAMS-QQ-A-250/11A - cancelled - 2008M&P AMS 4027CE N080701SAE Aluminum Alloy, Sheet and Plate 1.0Mg -0.60Si-0.28Cu-0.20Cr(6061;-T6 Sheet, T-651 Plate) Solution and Precipitation HeatTreatM&P AMS 4037CY P111201SAE Aluminum Alloy, Sheet and Plate 4.4Cu - 1.5Mg - 0.60Mn(2024; - T3 Flat Sheet, T351 Plate) Solution Heat TreatedM&P AMS 4048CW N100801SAE Aluminum Alloy Sheet and Plate, Alclad 5.6Zn - 2.5Mg - 1.6Cu -0.23Cr (Alclad 7075-O) Annealed or When Specified, "Asfabricated" (Alclad 7075-F)AMS 4049CW L101201SAE Aluminum Alloy Sheet and Plate, Alclad 5.6Zn - 2.5Mg - 1.6Cu -M&P0.23Cr (Alclad 7075; -T6 Sheet - T651 Plate) Solution andPrecipitation Heat TreatedAMS 4056DB G101001SAE Aluminum Alloy, Sheet and Plate 4.4Mg - 0.70Mn - 0.15CrM&P(5083-01)M&P AMS 4080CN N091201SAE Aluminum Alloy, Drawn Seamless Tubing 1.0Mg - 0.60Si -0.28Cu - 0.20Cr (6061-O) AnnealedM&P AMS 4081CC J080601SAE Aluminum Alloy Tubing, Hydraulic, Seamless, Drawn, Round1.0Mg - 0.60Si - 0.28Cu - 0.20Cr (6061-T4) Solution HeatTreated and Naturally AgedM&P AMS 4083DE L121101SAE Aluminum Alloy Tubing, Hydraulic, Seamless, Drawn, Round1.0Mg - 0.60Si - 0.28Cu - 0.20Cr- (6061-T6) Solution andPrecipitation Heat TreatedM&P AMS 4086BL N060901SAE Aluminum Alloy, Drawn, Round, Seamless Hydraulic Tubing4.4Cu-1.5Mg-0.60Mn (2024-T3) Solution Heat Treated, ColdWorked, and Naturally AgedAMS 4088BT K070301SAE Aluminum Alloy, Drawn, Seamless Tubing 4.4Cu-1.5Mg-M&P0.60Mn (2024-T3) Solution Heat Treated and Cold WorkedAMS 4107F051101SAE Alum Aly Die Forg, (7050-T14)M&PM&P AMS 4113CH E030701SAE Aluminum Alloy, Extruded Profiles 1.0Mg - 0.60Si - 0.28Cu -0.20Cr (6061-T6) Solution and Precipitation Heat TreatedM&P AMS 4115CU H090701SAE Aluminum Alloy, Rolled or Cold-Finished, Bars, Rods, Wire,and Flash Welded Rings Annealed 1.0Mg - 0.60Si - 0.2Cu -0.20Cr (6061-0)M&P AMS 4116CN H090701SAE Aluminum Alloy, Bars, Rods, and Wire 1.0Mg - 0.60Si - 0.3Cu -0.20Cr (6061-T4) Cold Finished, Solution Heat Treated andNaturally AgedM&P AMS 4117CM J090701SAE Aluminum Alloy, Rolled or Cold Finished Bars, Rods, and Wireand Flash Welded Rings 1.0Mg -0.60Si - 0.28Cu - 0.20Cr(6061; - T6, -T651) Solution and Precipitation Heat TreatedAMS 4120M&P AMS 4119Cancelled CN Can900101SAE Aluminum Alloy Bars, Rolled, Drawn, or Cold Finished 4.4Cu -1.5Mg - 0.60Mn (2024-T351) Stress Relief StretchedAMS 4120R020901SAE Aluminum Alloy, Rolled or Cold Finished Bars, Rods, and WireM&P4.4Cu - 1.5 Mg - 0.60Mn (2024) Solution Heat Treated andNaturally Aged (T4) Solution Heat Treated, Cold Worked, andNaturally Aged (T351)M&P AMS 4121CA H071101SAE Aluminum Alloy Bars, Rods, and Wire, Rolled or Cold Finished4.5Cu - 0.85Si - 0.80Mn - 0.50Mg (2014-T6) Solution andPrecipitation Heat TreatedM&P AMS 4123CN H060101SAE Aluminum Alloy, Rolled or Cold Finished Bars and Rods (7075-T651) Solution and Precipitation Heat TreatedM&P AMS 4124DG E120901SAE Aluminum Alloy, Rolled or Cold Finished Bars, Rods, and Wire5.6Zn-2.5Mg-1.6Cu-0.23Cr (7075-T7351) Solution HeatTreated, Stress Relieved by Stretching and OveragedM&P AMS 4128CN D071001SAE Aluminum Alloy Bars, Rolled or Cold Finished 1.0Mg - 0.60Si -0.30Cu - 0.20Cr (6061-T451) Solution Heat Treated and StressRelieved by Stretchingat BPS4000 rev(yy/mm/dd)SupersedingDocAMS 4132DF G130201SAE Aluminum Alloy, Die and Hand Forgings, Rolled Rings, andM&PForging Stock 2.3Cu-1.6Mg-1.1Fe-1.0Ni-0.18Si-0.07Ti (2618-T61) Solution and Precipitation Heat TreatedM&P AMS 4133CN E090301SAE Aluminum Alloy Forgings and Rolled Rings 4.4Cu -0.85Si -0.80Mn - 0.50Mg (2014-T6) Solution and Precipitation HeatTreatedAMS 4133M&P AMS 4135Cancelled CN Can860401SAE Aluminum Alloy Forgings 4.5Cu - 0.85Si - 0.80Mn - 0.50Mg(2014-T6) Solution and Precipitation Heat TreatedAMS 4141CE F081001SAE Aluminum Alloy Die Forgings 5.6Zn - 2.5Mg - 1.6Cu - 0.23CrM&P(7075-T73) Solution and Precipitation Heat TreatedAMS 4144BN F060501SAE Aluminum Alloy, Hand Forgings and Rolled Rings 6.3Cu -M&P0.30Mn - 0.18Zr - 0.10V - 0.06Ti (2219-T852/T851) SolutionHeat Treated, Mechanically Stress Relieved, and PrecipitationHeat-TreatedM&P AMS 4149D020901SAE Aluminum Alloy, Die and Hand Forgings 5.6n - 2.5Mg - 1.6Cu -0.23Cr (7175-T74) Solution and Precipitation Heat TreatedAMS 4150DG M130401SAE Aluminum Alloy, Extrusions and Rings 1.0Mg - 0.60Si - 0.28Cu -M&P0.20Cr - (6061-T6) Solution and Precipitation Heat TreatedM&P AMS 4162D030701SAE Aluminum Alloy, Extrusions 6.3Cu - 0.30Mn - 0.18Zr - 0.10V -0.06Ti (2219-T8511) Solution Treated, Stress Relief Stretched,Straightened, and Precipitation Heat TreatedM&P AMS 4173DG F130401SAE Aluminum Alloy, Extrusions 1.0Mg - 0.60Si - 0.30Cu - 0.20Cr(6061-T6511) Solution Heat Treated, Stress Relieved byStretching, Straightened, and Precipitation Heat TreatedM&P AMS 4181C030401SAE Aluminum Alloy, Welding Wire 7.0Si - 0.38Mg - 0.10Ti (4008)(UNS A94008)M&P AMS 4182CN G091201SAE Alum Aly Wire, Annealed 5.0Mg - 0.12Mn - 0.12Cr (5056-0)AnnealedAMS 4185DB E120201SAE Fill Mtl, Alum Braz, 12SI, (4047)M&P AMS 4188Cancelled Can861001SAE Wldg Wire AMS 4181M&P AMS 4188Cancelled Can861001SAE Wldg Wire AMS 4233M&P AMS 4188Cancelled Can861001SAE Wldg Wire AMS 4244M&P AMS 4188Cancelled Can861001SAE Wldg Wire AMS 4245M&P AMS 4188Cancelled Can861001SAE Wldg Wire AMS 4246M&PM&P AMS 4210CN K050301SAE Aluminum Alloy, Castings 5.0Si - 1.2Cu - 0.50Mg (355.0-T51)Precipitation Heat TreatedM&P AMS 4212CU K110201SAE Aluminum Alloy Castings 5.0Si - 1.2Cu - 0.50Mg (355.0-T6)Solution and Precipitation Heat TreatedM&P AMS 4214CN J080601SAE Castings, Aluminum Alloy Sand 5.0Si - 1.2Cu - 0.50Mg (355.0T71) Solution Heat Treated and OveragedM&P AMS 4215CN H080301SAE Aluminum Alloy, Castings 5.0Si - 1.2Cu - 0.50Mg (C355.0-T6)Solution and Precipitation Heat TreatedM&P AMS 4217CN H070401SAE Aluminum Alloy, Castings 7.0Si - 0.32Mg (A356.0-T6) (formerlyT6P Temper) Solution and Precipitation Heat TreatedM&P AMS 4218CN J100101SAE Aluminum Alloy Castings 7.0Si-0.35Mg (A356.0-T6) (formerlyT6P Temper) Solution and Precipitation Heat TreatedM&P AMS 4223CN D070401SAE Aluminum Alloy, Castings 4.5Cu - 0.70Ag - 0.30Mn - 0.25Mg -0.25Ti (A201.0-T4) Solution Heat Treated and Naturally AgedOk to use canc spec.M&P AMS 4224Cancelled - no s/s spec CN C100101SAE Aluminum Alloy Castings, Sand 4.0Cu - 2.1Ni - 2.0Mg - 0.30Cr -0.30Mn - 0.13T - 0.13V (243.0) StabilizedM&P AMS 4225CN D070601SAE Aluminum Alloy, Heat Resistant, Castings 5.0Cu - 1.5Ni -0.25Mn - 0.25Sb - 0.25Co - 0.20Ti - 0.20Zr (203.0-T6) SolutionHeat Treated and Precipitation Heat TreatedM&P AMS 4226Noncurrent CN A830101SAE Aluminum Alloy Castings, High Strength 5.0Cu - 0.35Mn -0.18Zr- 0.10V (224.0) Solution and Precipitation Heat Treated(Overaged)AMS 4227Cancelled - no s/s spec CN E050701SAE Aluminum Alloy, Casting, Sand, 8.0Cu 6.0Mg 0.50Mn 0.50Ni,Ok to use canc spec.M&PAs CastAMS 4229DA F120201SAE Aluminum Alloy Castings, High Strength 4.5Cu - 0.7Ag -M&P0.30Mn - 0.25Mg - 0.25Ti (A201.0-T7) Solution Heat Treatedand OveragedM&P AMS 4233C030301SAE Aluminum Alloy, Welding Wire 4.5 Cu - 0.70Ag - 0.30Mn -0.25Mg - 0.25Ti (A201.0-T7) Solution Heat Treated andOveragedat BPS4000 rev(yy/mm/dd)SupersedingDocAMS 4235CN B080301SAE Aluminum Alloy Castings 4.6Cu - 0.35Mn - 0.25Mg - 0.22Ti(A206.0-T71) Solution and Precipitation Heat TreatedM&P AMS 4236DF C130201SAE Aluminum Alloy Castings 4.6Cu - 0.35Mn - 0.25Mg - 0.22Ti(A206.0-T4) Solution Heat Treated and Naturally AgedM&P AMS 4237Cancelled - no s/s spec CN B070401SAE Aluminum Alloy Castings, Sand 4.6Cu - 0.35Mn - 0.25Mg -0.22Ti (206.0 - T71) Solution Heat Treated and Naturally AgedOk to use canc spec.M&P AMS 4241CN D091101SAE Aluminum Alloy Castings 7.0Si - 0.58Mg - 0.15Ti -0.06Be(D357.0 - T6) Solution and Precipitation Heat Treated DendriteArm Spacing (DAS) ControlledM&PAMS 4244CE B080701SAE Aluminum Alloy, Welding Wire 4.6Cu - 0.35Mn - 0.25Mg -0.22Ti for Welding A206.0 Type AlloysM&PAMS 4245CR E100401SAE Aluminum Alloy, Welding Wire 5.0Si - 1.2Cu - 0.50Mg (355)(UNS A03550)M&PAMS 4246Noncurrent CP D080201SAE Aluminum Alloy, Welding Wire 7.0Si - 0.52Mg (357) (UNSA03570)M&PAMS 4260Not Acceptable to Use atParker HannifinAerospace CL G080601SAE Alum Aly Cast, Invest (356.0-T6)BPS4829AMS 4260 rev. G unacceptable for ParkerUse. BPS4829 created as replacement.M&PAMS 4261CN F091201SAE Aluminum Alloy Castings, Investment 7.0Si - 0.32Mg (356.0 -T51) Precipitation Heat TreatedM&P AMS 4280CN J080601SAE Aluminum Alloy Castings, Permanent Mold 5.0Si - 1.2Cu -0.5Mg (355.0-T71) Solution Heat Treated and OveragedM&P AMS 4284DC J110301SAE Aluminum Alloy Castings, Permanent Mold 7.0Si - 0.30Mg(356.0-T6) Solution and Precipitation Heat TreatedM&P AMS 4289CN-011101SAE Aluminum Alloy Castings 7.0Si - 0.55Mg - 0.12Ti (F357.0-T6)Solution and Precipitation Heat TreatedM&P AMS 4291CT H101001SAE Aluminum Alloy, Die Castings 8.5Si - 3.5Cu (A380.0-F) (SeeAS1990) As CastM&P AMS 4315CK-050701SAE Aluminum Alloy Sheet and Plate 5.6Zn - 2.5Mg - 1.6Cu - 0.23Cr7075: (-T76 Sheet, -T7651 Plate) Solution and PrecipitationHeat TreatedM&PAMS 4316CY A111101SAE Aluminum Alloy, Alclad Sheet and Plate 5.6Zn - 2.5Mg M&P AMS 4437DM F140201SAE Magnesium Alloy Castings, Sand 8.7Al - 0.70Zn (AZ91C-T6)Solution Heat Treated and AgedM&P AMS 4507BW H011101SAE Copper Alloy (Brass), Sheet, Strip, and Plate 70Cu - 30Zn HalfHard (H02)M&P AMS 4510CN G010501SAE Phosphor Bronze, Sheet, Strip, and Plate 94.5Cu - 4.0Sn -0.19P Spring Temper (H08)M&P AMS 4511A040701SAE Copper Beryllium Alloy Castings 97Cu-2.1Be-0.52(Co+Ni)-0.28Si Solution and Precipitation Heat Treated (TFOO)M&P AMS 4530CY J110901SAE Copper-Beryllium Alloy Sheet, Strip, and Plate 98Cu - 1.9BeSolution Heat Treated (TB00)M&P AMS 4533DF D130201SAE Copper-Beryllium Alloy, Bars and Rods 98Cu - 1.9Be Solutionand Precipitation Heat Treated (TF00, formerly AT)-UNSC17200M&PAMS 4597CY A111201SAE Copper-Nickel-Tin Alloy, Bars and Rods 77Cu - 15Ni - 8SnSolution Annealed, Cold Finished and Spinodal Hardened (TXTS)M&PAMS 4631Noncurrent CL E880401SAE Aluminum Bronze Rods, Bars, and Forgings 90.5Cu - 7.5Al -1.95: Stress RelievedM&P AMS 4633CL A031201SAE Bronze, Aluminum Silicon, Rods, Bars, and Forgings 90Cu -7.0Al - 1.8Si Drawn and Stress Relieved (HR50)M&P AMS 4634CL B090301SAE Aluminum Bronze Bars, Rods, and Forgings 905Cu - 7.5Al -1.9Si Stress RelievedM&P AMS 4635CL F090701SAE Aluminum Bronze Bars, Rods, and Forgings 87Cu - 9Al - 3FeStress RelievedM&P AMS 4640CV H110501SAE Aluminum Bronze, Bars, Rods, Shapes, Tubes, and Forgings81.5Cu - 10.0Al - 4.8Ni - 3.0Fe Drawn and Stress Relieved(HR50) or Temper Annealed (TQ50)M&PAMS 4650DF M130201SAE Copper-Beryllium Alloy, Bars, Rods, Shapes and Forgings98Cu - 1.9Be Solution Heat Treated TB00 (A)M&P AMS 4651CN C050701SAE Copper-Beryllium Alloy, Bars and Rods 98Cu - 1.9Be (CDA172) Hard Temper (TD04)M&P AMS 4674CN G060901SAE Nickel - Copper Alloy, Corrosion-Resistant, Bars and Forgings67Ni - 30Cu - 0.04S Free MachiningM&P AMS 4701CN G091001SAE Copper Wire, Oxygen-Free 99.95 (Cu+Ag) Annealed M&P。

10/848环球农化 近日,欧盟发布公告Commission Implementing Regulation（EU）2018/524, 该公告决定将2018年4月30日到期的24种农药活性物质的有效期延长至2019年4月30日，同时对欧盟批准的农药活性物质清单（EU）No. 540/2011进行了相应的修订。

该决定于2018年4月1日正式生效。

有效期延长的24种活性物质名单如下：英文名称中文名称备注Bacillus subtilis str. QST 713枯草芽孢杆菌-Clodinafop 炔草酯-Clopyralid 二氯吡啶酸-Cyprodinil 嘧菌环胺候选替代物质Candidate for Substitution (CfS)Dichlorprop-P 2，4-滴丙酸-Fosetyl 乙膦酸（弗赛得）-Mepanipyrim 嘧菌胺-Metconazole 叶菌唑候选替代物质Candidate for Substitution (CfS)Metrafenone 苯菌酮-Pirimicarb抗蚜威候选替代物质Candidate for Substitution (CfS)Pseudomonaschlororaphis strainMA342绿叶假单胞菌MA342株系-Pyrimethanil嘧霉胺-英文名称中文名称备注Quinoxyfen 喹氧灵候选替代物质Candidate for Substitution (CfS)Rimsulfuron (akarenriduron)玉嘧磺隆-Spinosad多杀菌素Thiacloprid 噻虫啉候选替代物质Candidate for Substitution (CfS)Thiamethoxam噻虫嗪--Thiram 福美双-Tolclofos-methyl甲基立枯磷-Triclopyr 绿草定（三氯吡氧乙酸）-Trinexapac(aka cimetacarb ethyl)抗倒酯-Triticonazole灭菌唑-Ziram福美锌候选替代物质Candidate for Substitution (CfS) 此外，根据英国卫生安全署HSE 最新消息，目前欧盟已经完成了对拿草特（Propyzamide）、灭草松（Bentazone）、氯吡脲（Forchlorfenuron）、噻菌胺（Silthiofam）、苯酰菌胺（Zoxamide）的再评审工作，上述活性物质再评审顺利通过。

SAFETY DATA SHEETDREXEL MALATHION 5EC INSECTICIDE/MITICIDEProduct Name:Drexel Malathion 5EC Insecticide/MiticideEPA Reg No.:19713-217CAS NO:121-75-5Formula:C10H19O7PSCompany:Drexel Chemical Company1700 Channel AvenueMemphis, TN 38106Identifiers:EINECS: 204-497-7RTECS: WM8400000DOT label: UN-3082, Environmentally hazardous substances, liquid, n.o.s., (Malathion), 9, PG-III, Marine Pollutant, RQ 100 Lbs.Emergency Telephone Number:CHEMTREC Drexel Chemical Co.Tel: 1-800-424-9300 901-774-4370This product is an EPA FIFRA registered pesticide. Some of the classifications on this SDS are not the same as the FIFRA label. Certain sections of this SDS are superseded by federal law governed by EPA for a registered pesticide. Please see Section 15: REGULATORY INFORMATION for explanation.GHS classification:Health hazards: Acute toxicity – oral Category 4Skin corrosion/irritation Category 2Eye damage/irritation Category 2BAspiration hazard Category 1Specific target organ toxicity–(single exposure) Category 1Specific target organ toxicity–(repeated exposure) Category 2Aquatic acute toxicity Category 1Aquatic chronic toxicity Category 1Corrosive to metals Category 1GHS label elements:Signal word: DangerHazard statements: Harmful if swallowed.Harmful if inhaled.Causes eye irritation.May be fatal if swallowed and enters airways.Causes damage to nervous system.May cause damage to nervous system through prolonged or repeated exposure.Very toxic to aquatic life.Very toxic to aquatic life with long lasting effects.May be corrosive to metals.Precautionary statements:Prevention: Wash thoroughly after handling. Avoid breathingdust/fume/gas/mist/vapors/spray. Wear protective gloves chemically resistant tothis material. Examples of preferred glove barrier materials include: Neoprene,Nitrile/butadiene rubber (“nitrile” or “NBR”) or Polyvinyl chloride (“PVC” or “vinyl”).Wear eye protection/face protection (see Section 8). Wash face and handsthoroughly after handling. Do not eat, drink or smoke when using this product.Use only outdoors or in well-ventilated area. Prevent from entering into sewers,waterways and/or groundwater. See Section 12: Ecological Information. Keeponly in original container.Response: If swallowed: Immediately call a poison control center/doctor. Rinse mouth. DoNOT induce vomiting.If on skin: Wash with plenty of water. If skin irritation occurs: Get medicaladvice/attention. Take off contaminated clothing and wash it before reuse.If in eyes: Rinse cautiously with water for several minutes. Remove contactlenses, if easy to do. Continue rinsing. If eye irritation persists: Get medicaladvice/attention.If exposed: Call poison center/doctor. Specific treatment see Note toPhysician, Section 4: First-Aid Measures. Absorb spillage to prevent materialdamage.Storage: Store locked up in corrosive resistant container (high density polyethylene).Disposal: Disposal of contents/container must be in accordance with your local or arearegulatory authorities.Components CAS No. % By Wt. OSHA PEL ACGIH TLVActive Ingredient:Malathion 121-75-5 57.0% N/A 10 mg/m3Inert Ingredients: N/A 43.0% N/A N/AEye Contact: Hold eye open and rinse slowly and gently with water for 15 to 20 minutes. Remove contact lenses, if present, after the first 5 minutes, then continue rinsing eyes for at least 10 minutes. Obtain medical attention without delay, preferably from an ophthalmologist.If Swallowed: Call a poison control center or doctor immediately for treatment advice. Rinse mouth with water, have person sip a glass of water if able to swallow. Do not induce vomiting unless told to do so by the poison control center or doctor. Do not give anything by mouth to an unconscious person. Have product label with you when calling a poison control center or doctor.Skin Contact: Immediately flush skin with water for 15 minutes while removing contaminated clothing and shoes. Get medical attention if symptoms occur. Wash clothing before reuse. Destroy contaminated leather items such as shoes, belts, and watchbands.If Inhaled: Move person to fresh air. If person is not breathing, call 911 or an ambulance, then give artificial respiration, preferably mouth-to-mouth, if possible. Call a poison control center or doctor for further treatment advice.Note to Physician: This product may cause cholinesterase inhibition. Atropine is antidotal. 2-PAM may be effective as an adjunct to Atropine. May pose an aspiration pneumonia hazard. Contains petroleum distillate.Fire Hazards: Closed containers may rupture if exposed to excess heat or flame due to a build-up of internal pressure. Material will decompose rapidly when exposed to heat (>212oF/100oC) and flame, increasing the risk of explosion. Thermal decomposition during a fire can produce fumes and irritating gases.Flammability classification (OSHA 29 CFR 1910.1200): CombustibleFlash point: 155°F (68.3°C)Lower flammable limit (% by volume): N/AUpper flammable limit (% by volume): N/AFire Fighting Procedures: Keep people away. Isolate fire and deny unnecessary entry. Evacuate the area and fight the fire from upwind at a safe distance to avoid hazardous vapors or decomposition products. Dike and collect fire-extinguishing water to prevent environmental damage and excessive waste runoff.Firefighting media: Use dry foam, dry chemical, carbon dioxide, or water fog when fighting fires involving this product. Do not use water jet, as this may spread burning material. Minimize the use of water to avoid environmental contamination. Contain all runoff.Special Protective Equipment for Firefighters: Wear positive-pressure self-contained breathing apparatus (SCBA) and protective firefighting clothing (includes firefighting helmet, coat, trousers, boots, and gloves). Use full face shield and operate in positive pressure mode. Avoid contact with this material during firefighting operations. If contact is likely, change to full chemical resistant firefighting clothing with self-contained breathing apparatus. If this is not available, wear full chemical resistant clothing with self-contained breathing apparatus and fight fire from a remote location. For protective equipment in post-fire or non-fire clean-up situations, refer to the relevant sections.Hazardous Combustion Products: Oxides of sulfur and phosphorus-containing compounds. Incomplete combustion may lead to formation of carbon monoxide and/or other asphyxiants.NFPA: Health: Flammability: Reactivity:3 2 0(Rating: 4-Extreme, 3-High, 2-Moderate, 1-Slight, 0-Insignificant)Steps to be taken if Material is Released or Spilled:∙Contain spilled material if possible. Small spills: Contain and absorb spilled material with inert, non-combustible absorbent material, sweep up. Collect in suitable and properly labeled containers. Large spills: Contact Drexel Chemical Co. for clean-up assistance. See Section 13: Disposal Considerations, for additional information.Personal Precautions:∙Isolate area. Keep unnecessary and unprotected personnel from entering the area. Refer to Section 7, Handling, for additional precautionary measures. Spilled material may cause a slipping hazard. Ventilate area of leak or spill. Use appropriate safety equipment. For additional information, refer to Section 8: Exposure Controls and Personal Protection.Environmental Precautions: Prevent spilled material from entering into soil, ditches, sewers, waterways and/or groundwater. See Section 12: Ecological Information.KEEP OUT OF REACH OF CHILDRENHandling: General Handling: Avoid contact with eyes, skin, and clothing. Wash thoroughly with soap and water after handling. Do not swallow. Avoid breathing vapor. Use with adequate ventilation. Wear chemicalprotective equipment when handling. Keep away from heat, sparks and flame. See Section 8: ExposureControls and Personal Protection.Storage: Store locked up in a cool, dry, well-ventilated area designated specifically for pesticides and away from heat sources. Keep in original containers and keep containers closed when not in use. Never heat above131°F (55°C), and do not store for long periods of time at a temperature in excess of 77°F (25°C). Do notstore near children, food, foodstuffs, drugs or potable water supplies.Exposure Limits: (8-Hour TWA): Malathion 15 mg/m3 (Skin); 1mg/m3 (Inhalable)Personal Protection:Eye/Face Protection: Wear safety glasses with side shields or chemical splash goggles to prevent vapors or mists from entering the eyes. If using a full face shield, always use safety glasses or goggles along with the face shield to ensure adequate protection of the eyes.Skin Protection: Use protective clothing chemically resistant to this material. Selection of specific items such as face shield, boots, apron, or full body suit will depend on the task. Safety shower should be located in immediate work area. Remove contaminated clothing immediately, wash skin area with soap and water, and launder clothing before reuse or dispose of properly. Items which cannot be decontaminated, such as shoes, belts andwatchbands, should be removed and disposed of properly.Hand protection: Use gloves chemically resistant to this material. Examples of preferred glove barrier materials include: Neoprene, Nitrile/butadiene rub ber (“nitrile” or “NBR”) or Polyvinyl chloride (“PVC” or “vinyl”).Respiratory Protection: Respiratory protection should be worn when there is a potential to exceed the exposure limit requirements or guidelines. When handling in enclosed areas, when large quantities of mists are generated or prolonged exposure is possible in excess of the 8-houir TWA, use a respirator with either an organic vapor-removing cartridge with a prefilter approved for pesticides (MSHA/NIOSH approval number prefix TC-23C) or a canister approved for pesticides (MSHA/NIOSH approval number prefixTC-14G).Ingestion: Avoid ingestion of even very small amounts; do not consume or store food or tobacco in the work area; wash hands and face before smoking or eating.Engineering Controls:Ventilation: When handling this product proper ventilation is required to maintain exposure below the 8-hour TWA. Ventilate all transport vehicles prior to unloading. Facilities storing or utilizing this material should beequipped with and eyewash facility and safety shower.Physical State: LiquidColor: GoldenOdor: MercaptanFlash Point: 155°FVapor Pressure (mmHg): <24.8Boiling Point: >300°FVapor Density (air = 1): N/ABulk Density (H2O = 1): 1.07 g/ccFreezing Point: N/ASolubility in water: EmulsifiespH: 3 -5 (5% solution)Viscosity: N/AStability/Instability: Thermally stable if handled at typical use temperatures and in closed containers.Conditions to Avoid: Avoid heat of open flame. Avoid high temperatures above 130°F (54.4°C). Avoid reducing agents.Incompatible Materials: Malathion can corrode iron, steel, tin plate and copper.Hazardous Polymerization: Will not occurThermal Decomposition: Can include oxides of sulfur and phosphorus-containing compounds. Incomplete combustion may lead to formation of carbon monoxide and/or other asphyxiants.Information provided for the active ingredient Malathion:Acute Toxicity:Ingestion:∙Oral, LD50, (rat): >550 mg/kgDermal:∙Dermal, LD50, (rabbit): >2,000 mg/kgInhalation:∙Inhalation, 4 h, LC50, (rat): >5.2 mg/lEye Irritation:∙Slightly irritating (rabbit)Skin Irritation:∙Slightly irritating (rabbit)Sensitization Skin:∙Non-sensitizer (guinea pig)Chronic Toxicity:∙None knownCarcinogenicity:∙Not listed as carcinogenic by ACGIH, IARC, OSHA or NTPTeratogenicity, mutagenicity, and other reproductive effects: None knownThe information presented here is for the active ingredient Malathion.ENVIRONMENTAL FATE:∙This product is toxic to birds, fish, aquatic invertebrates, aquatic life, and stages of amphibians and highly toxic to bees.Persistence and Degradability:∙Medium mobility, readily biodegradableAquatic Toxicity:∙Daphnia magna, 48 h, EC50: 0.72 mg/L∙Green Algae, 72 h, LC50: 4.06 mg/L∙Rainbow Trout, 96 h, LC50: 0.18 mg/kgBird Toxicity:∙Bobwhite Quail, LD50: 359 mg/kg∙Mallard Duck, LD50: 1485 mg/kgIf wastes and/or containers cannot be disposed of according to the product label directions, disposal of this material must be in accordance with your local or area regulatory authorities. This information presented below only applies to the material as supplied. The identification based on characteristic(s) or listing may not apply if the material has been used or otherwise contaminated. It is the responsibility of the waste generator to determine the toxicity and physical properties of the material generated to determine the proper waste identification and disposal methods in compliance with applicable regulations. If the material as supplied becomes a waste, follow all applicable regional, national and local laws.DOT (<19.5 gals): Not regulatedDOT (>119 gals): UN-3082, Environmentally hazardous substances, liquid, n.o.s., (Malathion), 9, PG-III, Marine pollutant, RQ 100 lbs.IMDG/IMO (vessel): UN-3082, Environmentally hazardous substances, liquid, n.o.s., (Malathion), 9, PG-III, Marine pollutant, RQ 100 lbs.IATA/ICAO (air): UN-3082, Environmentally hazardous substances, liquid, n.o.s., (Malathion), 9, PG-III, Marine pollutant, RQ 100 lbs.Freight Description: Agricultural Insecticide, Liquid, N.O.S.ERG Guide No.: 171This information is not intended to convey all specific regulatory or operational requirements/information relating to this product. Additional transportation system information can be obtained through an authorized sales or customer service representative. It is the responsibility of the transporting organization to follow all applicable laws, regulations and rules relating to the transportation of the material.OSHA Hazard Communication Standard:∙This product is a “Hazardous Chemical” as defined by the OSHA Hazard Communication Standard, 29 CFR 1910.1200.∙EPA FIFRA INFORMATION:This chemical is a pesticide product registered by the United States Environmental Protection Agency and is subject to certain labeling requirements under federal pesticide law. These requirements differ from the classification criteria and hazard information required for safety data sheets (SDS), and for workplace labels of non-pesticide chemical. The hazard information required on the pesticide label is listed out below.The pesticide label also includes other important information, including directions for use.∙EPA/CERCLA Reportable Quantity: Malathion: (CAS: 121-75-5): 100 poundsSARA/TITLE III:∙Sec. 302. Extremely Hazardous Substance Notification: This material is not known to contain any Extremely Hazardous Substances.∙Sec. 311/312. Hazard Categories:Fire HazardImmediate health hazardChronic health hazard∙Sec. 313. Toxic Chemical(s): Malathion (CAS: 121-75-5)∙RCRA Waste Code: Not applicableCalifornia Proposition 65 (Safe Drinking Water and Toxic Enforcement Act of 1986):∙This product is listed.Toxic Substances Control Act (TSCA):∙All components of this product are on the TSCA Inventory or are exempt from TSCA Inventory requirements under40 CFR 720.30Drexel Chemical Company recommends that each customer or recipient of this SDS to study it carefully and consult appropriate expertise, as necessary or appropriate, to become aware of and understand the data contained in this SDS and any hazards associated with the product. The information herein is provided in good faith and believed to be accurate as of the effective date shown below. However, no warranty, express or implied, is given. Regulatory requirements are subject to change and may differ between various locations. It is the buyer’s/user’s responsibility to ensure that his activities comply with all federal, state, provincial or local laws. The information presented here pertains only to the product as shipped. Since conditions for use of the product are not under the control of the manufacturer, it is the buyer’s/user’s duty to determine the conditions necessary for the safe use of this product. Due to the proliferation of sources for information such as manufacturer-specific SDSs, we are not and cannot be responsible for SDSs obtained from any source other than ourselves. If you have obtained an SDS from another source or if you are not sure that the SDS you have is current, please contact us for the most current version.Date Issued: November 12, 2015Supersedes: April 8, 2015。

碧云天生物技术/Beyotime Biotechnology 订货热线：400-168-3301或800-8283301 订货e-mail ：******************技术咨询：*****************网址：碧云天网站 微信公众号维生素B12 (≥98%, Reagent grade)产品编号 产品名称包装 ST1740-250mg 维生素B12 (≥98%, Reagent grade) 250mg ST1740-1g 维生素B12 (≥98%, Reagent grade) 1g ST1740-5g维生素B12 (≥98%, Reagent grade)5g产品简介：CAS Number Chemical Formula Molecular WeightPurity Grade 68-19-9C 63H 88CoN 14O 14P1355.37≥98%Reagent grade基本信息(General Information)：Name (Chinese) 维生素B12 Name (English) Vitamin B12 Specifications Reagent grade, ≥98% Chemical Formula C 63H 88CoN 14O 14P Synonym (Chinese) 氰钴胺Synonym (English)alpha-(5,6-Dimethylbenzimidazolyl)cyanocobamide;CN-Cbl; Cyanocob(III)alamin; CyanocobalaminBeilstein Registry No. 4122889 EINECS Number 200-680-0 MDL Number MFCD00151092 UNSPSC Code 12352200 产品描述(Description)：Biochem/physiol Actions维生素B12(钴胺素)是指一组化学相关的含钴分子，参与细胞过程，如DNA 合成，脂肪酸合成，能量产生和调节。

European Association for theDevelopment of Renewable Energies, Environmentand Power Quality (EA4EPQ)International Conference on Renewable Energies and Power Quality(ICREPQ’12)Santiago de Compostela (Spain), 28th to 30th March, 2012Comparison of methods for implementing virtual synchronous machine oninvertersYong Chen 1, Ralf Hesse 2, Dirk Turschner 3 and Hans-Peter Beck 41234Institute of Electrical Power Engineering Clausthal University of TechnologyLeibnizstrasse 28, 38678 Clausthal-Zellerfeld (Germany) 1Phone:+0049-5323-72-3819, e-mail: yong.chen@tu-clausthal.de2Phone:+0049-170-5021628, e-mail: email@iehw.de3Phone:+0049-5323-72-2592, e-mail: dirk.turschner@tu-clausthal.de 4Phone:+0049-5323-72-2570, e-mail: mendt@iee.tu-clausthal.deAbstractVirtual Synchronous Machine also called VISMA [1] is a control algorithm to make an inverter operated as a conventional electromechanical synchronous machine. It is a promising solution to overcome the problems of the grid stability and quality, which have been exacerbated by increasing integration of distributed generation units into the grid. Compared to the conventional power plants, in which the synchronous machine dominate, the distributed generation units have either significantly smaller or no rotating mass and damping effect. These weaknesses can be compensated by using the VISMA concept and thus the power system quality will be improved. Furthermore, the penetration level of the DG sources won’t be restricted any more.Up to now the VISMA was implemented by using a voltage-to-current model on a hysteresis controlled inverter [1][2][3]. This method will be called VISMA-Method 1 here. Since the most products of inverters in the market are PWM controlled, the VISMA-Method 1 cannot be easily applied on these inverters. Therefore, a new method is developed to implement the VISMA by using a current-to-voltage model on the currently widely applied PWM controlled inverter. This new method is called VISMA-Method 2 in this paper and will be compared with the VISMA-Method 1 by simulation results.Key wordsVirtual Synchronous Machine (VISMA), inverter, hysteresis controller, pulse-width modulation (PWM), distributed generation (DG), stand-alone grid, virtual rotating mass, virtual damping1. IntroductionThe diffusing utilization of the renewable energy resources is driven by the limited fossil energy store on the one hand and the exacerbated environmental issues as well as energy politics on the other hand.The diversity of the renewable energies and its strong dependence on the geological location and meteorological situation make the change that the electricity will be generated more and more by small distributed generation (DG) units. Most of these DG technologies only consider supplying maximum power into the grid but taken the stability of the power system not into account. Generally, a few small-size DG units will not influence the safe operation of the power network in the presence of large centralized power stations thus their influences can be neglected. But with a larger numbers of DG units with higher capacities, the overall dynamics of power systems are significantly affected [4]. Therefore the solutions to improve the power system stability and at the same time ensure the increasing integration of the DG units are necessary.The concept of virtual synchronous machine describes a new type of grid feeding inverter, which operates with a storage system entirely as an electromechanical synchronous machine. The basic idea of the VISMA bases on reproducing the static and dynamic properties of a real synchronous machine on a power electronic interface between a DG unit and the grid, in order to inherit the advantages of a synchronous machine in consideration of power system stability such as adjustable active and reactive power, dependence of the grid frequency on the rotor speed and the effect of the rotating mass and damping windings as well as stable operation with a high parallelism level. Fig. 1 illustrates the basic idea of the VISMA.Fig. 1. Basic idea of the VISMA.This paper presents firstly two methods for impelmenting the VISMA on an inverter. Then the static and dynamic properties of both methods are compared by the simulation results in a parallel operation with the stiff grid. Futhermore it is also disscussed that whether both VISMA-Methods are able to be operated in a stand-alone grid. Finally the relavant conclusions are drawed at the end of this paper.2.Implementation Methods of the VISMAIn this section two methods to implement the VISMA on an inverter will be discussed here. They will be called VISMA-Method 1 and 2 in this paper. The VISMA-Method 1 was already presented in [1][2][3] and will be applied as a reference here for the comparison with the VISMA-Method 2.A. VISMA-Method 1: using voltage-to-current modelThe complete VISMA functional chain is shown in Fig. 2. It starts with the real-time measurement of the grid voltage to feed the virtual synchronous machine algorithm on the process computer and delivers the stator currents of the virtual synchronous machine as the results which presented as process variables. The fast hysteresis controlled inverter carries over the current signals to drive these currents at the grid immediately.Fig. 2. Concept of the VISMA-Method 1.The synchronous machine model used in this method is shown in Fig. 3 and was introduced in [5].Fig. 3. Block diagram of the VISMA-Model 1. B.VISMA-Method 2: using current-to-voltage model Compared with the VISMA-Method 1, the currents will be measured in the VISMA-Method 2 and the reference voltage will be calculated in the VISMA-Model 2, and then sent to a pulse-width modulator, which generates switch signals for the inverter. The inductors L f und capacitors C f are used to filter the harmonics of the output voltage of the inverter. Fig. 4 demonstrates the basic concept of the VISMA-Method 2.Fig. 4. Concept of the VISMA-Method 2.The synchronous machine model used in VISMA-Method 2 is a current-to-voltage model as shown in Fig.5. This is an inverse model of VISMA-Model 1, namely the current as input and voltage as output. After the model inversion a differentiator occurs, which could lead to instability of the model. Hence a low-pass filter should be applied to reduce the disturbance of the model input (current i grid) and enable a stable computing process of VISMA-Model 2.Fig. 5. Block diagram of the VISMA-Model 2. 3.Simulation ParametersThe simulations presented in this paper were carried out in Matlab-Simulink. The important parameter setups during the simulations are shown in table I.Table I. – Simulation parameters Voltage of DC site ±350V Nominal frequency 50Hz Nominal phase voltage (rms) 230V Inductor L f4mH Capacitor C5µF Tolerance band of hysteresiscontroller for phase currents±1ASwitching frequency of the IGBT inverter2,8kHz ~ 15kHz forVISMA-Method 115kHz for VISMA-Method 2 using PWM controllerTime step for simulation 1µs4.Parallel Operation with Stiff GridIn this section the two VISMA-Methods are discussed under the parallel operation with a stiff grid. The static and dynamic properties of the VISMA-Method 2 are compared with the reference VISMA-Method 1 by simulation results.A. Synchronisation of the VISMA with the gridThe VISMA must be synchronized with the grid firstly before connecting to the grid, since an adverse switching could lead to large transient currents between the VISMA and the grid, which could damage the equipments. Due to the different control concepts, both VISMA-Methods will be synchronized with the grid in different ways.Since the currents in the VISMA-Method 1 are controlled directly by using a hysteresis controller, the transient currents can be regulated nearly to zero by setting the reference currents closely to zero. After that, the VISMA can be connected to the grid, because the hysteresis controller and IGBT-module track the reference currents very fast.Compared to the VISMA-Method 1 the synchronizing of the VISMA-Method 2 is more complicated, since the currents between VISMA and grid cannot be directly controlled but only indirectly through the voltage controller. In this case the VISMA behaves as a voltage source. Therefore the VISMA can be synchronized with the grid in the same way as a real synchronous generator. Thereby the following parameters should be adjusted according to the grid voltage at PCC: amplitude, phase and frequency. The voltage difference between VISMA and grid should be so small that transient currents values are acceptable.B.Power setting of the VISMAThe power of the VISMA can be set similarly as a real synchronous machine. The following shows separately the active and reactive power setting of both VISMA-Methods with discussions.1). Active power setting of the VISMAThe active power of the VISMA can be easily set by adjusting the model parameter M mech, which is called virtual torque. Fig.6 shows the active power setting of the VISMA for both methods.Fig. 6. Active power setting of the VISMA (left: VISMA-Method 1; right: VISMA-Method 2).The simulation results prove that the VISMA-Method 2 is able to behave the same dynamic property as the VISMA-Method 1. A positive torque means the VISMA supplies an active power into the grid and operates as a generator. For a negative torque the active power will be taken from the grid and then the VISMA operates as a motor.The only difference between both VISMA methods consists in the noise component of the P vsima. In VISMA-Method 1, because of the hysteresis controller, which works at a fixedtoleranceband, the switching frequency of the inverter is not constant but varying within a frequency band. Therefore there are harmonics with different frequency terms in the output currents. However, in Method 2, by using PWM-controller a constant switching frequency can be reached thus the output of the inverter will be more easily and better filtered by selecting a proper filter.2). Reactive Power setting of the VISMAThe reactive power of the VISMA can be regulated by setting the virtual excitation E p in the same way just as a real synchronous machine in a power plant. This will be demonstrated in Fig. 7 through the simulation results. Fig. 7. Reactive power setting of the VISMA (left: VISMA-Method 1; right: VISMA-Method 2).Both VISMA-Methods supply a capacitive reactive power while over excited and an inductive reactive power while under excited. The VISMA-Method 2 has the same dynamic property as the VISMA-Method 1 but the output signal has a lower noise because of the PWM-controller compared to VISMA-Method 1.The power of the VISMA can be regulated dynamically during the changes of the grid frequency and voltage, in case that the frequency and voltage controls are added to the VISMA [6].C.Reaction of the VISMA to a grid frequency dropIn this section the dynamic properties of both VISMA-Methods, the virtual rotating mass and virtual damping, are compared by simulations results.1). Different virtual rotating massFig.8 recorded the simulation results which demonstrated how both VISMA-Methods respond to a grid frequency drop from 50Hz to 49.5Hz with different virtual rotating mass.Fig. 8. Reaction of the VISMA to a frequency drop with different virtual mass J VISMA (left: VISMA-Method 1; right: VISMA-Method 2).It can be clearly seen that both VISMAs provide an active power into the grid immediately as the grid frequency drops. Comparing the power reactions with J VISMA= 0.1kgm2, 0.3kgm2, and 0.5kgm2, it can also be observed in both VISMA methods that the VISMA with a larger virtual mass will provide more active power into the grid and therefore the grid will be more supported.2). Different virtual dampingThe virtual damping of the VISMA can reduce the oscillations in the grid. To prove this effect in VISMA-Method 2, the simulations with two different damping factors k d were carried out and the results are compared with the VISMA-Method 1. It is demonstrated that the virtual damping can also be realized in the VISMA-Method 2 as Method 1, which is observed in Fig. 9 that a larger damping factor has a stronger effect on reducing frequency and power oscillation of both VISMAs.D.Reaction of the VISMA to a voltage dropThe VISMA can support the grid during a voltage drop by supplying a capacitive reactive power. This dynamic property can be achieved in both VISMA methods as shown Fig. 10.Fig. 9. Reaction of the VISMA to a frequency drop with different virtual damping k d (left: VISMA-Method 1; right:VISMA-Method 2).Fig. 10. Reaction of the VISMA to a voltage drop (left: VISMA-Method 1; right: VISMA-Method 2).5.Failure of Stiff Grid – Island ModeIn the following section the island mode of both VISMA-Methods will be investigated by simulation. At the beginning both VISMAs are connected with the grid. After 0.2s the VISMAs will be switched off from the grid and they should build a local stand-alone grid. In all simulations the VISMA didn’t have frequency and voltage control mechanisms.A. Island mode of the VISMA-Method 1For the parallel operation with the stiff grid, the capacitors which are shown in green color in Fig. 11 are not necessary in the VISMA-Method 1, because it presents itself as a current source. If there is no stiff grid in this configuration, then the VISMA cannot operate as a synchronous machine, since no currents flow in the inductors and the hysteresis controller cannot work properly. Therefore, extra capacitors must be installed in the VISMA for the island function, see Fig. 11.Fig. 11. Enable the island function of the VISMA-Method 1 byextending the capacitors.Fig. 12 shows the simulation results under the condition that the VISMA changed from grid connected mode to island mode in cases of without and with a load.Fig. 12. Output voltage of the VISMA-Method 1 by changing to island mode (filter capacators C = 5µF, left: VISMA without load; right: VISMA with a load).It is obviously to see that the VISMA has built the voltage continuously after switching off the public grid. Without a load the voltages have a large distortion, because the switching frequency of the hysteresis controller is varying and the LC-filter could not filter out all frequency parts; whereas the VISMA under island mode with a resistive load, the harmonics could be damped almost completely and rapidly. Another way to reduce the harmonics is to choose larger capacitors and make sure that the corner frequency of the LC-filter is under the minimal switching frequency of the hysteresis controller.B.Island mode of the VISMA-Method 2For VISMA-Method 2 a modification of the hardware configuration is not necessary. The VISMA operates here as a voltage source. Under the same simulation conditions the VISMA-Method 2 provided following results illustrated in Fig.13.Fig. 13. Output voltage of the VISMA-Method 2 by changing to island mode (filter capacators C = 5µF, left: VISMA without load; right: VISMA with a load).Firstly, the VISMA-Method 2 could build the three phase voltages immediately after switching off the public grid. Secondly, the voltages of the VISMA have almost no harmonics compared to the VISMA-Method 1 because of the constant switching frequency of the PWM controller and the proper output filter. In the case of VISMA with a load into island mode, the voltages dropped in short period and then rose quickly to a stabile value. Because of the virtual inertial of the VISMA the voltages cannot collapse suddenly. In order to keep a stable long-term voltage under island mode, the voltage and frequency controller must be applied. parison of both VISMA-MethodsIn table II a comparison of both VISMA-Methods is presented by considering the important properties of the VISMA system.Table II. – Comparison of VISMA-MethodsVISMA-Method 1 VISMA-Method 2VISMA-Modelvoltage-to-currentmodelcurrent-to-voltagemodelControlmechanismHysteresis controller PWM controller Control variable Phase currents Phase voltages MeasurementvariablePhase voltages amPCCPhase currents inoutput inductors Switchingfrequency(assumed: max.f s=15kHz forIGBT)2,8kHz ~ 15kHz insimulation (dependson the setting ofhysteresis controller)15kHz in simulation(depends on thesetting of PWMcontroller)Synchronizingwith the gridVISMA currentsalmost equal to zeroThe same as the realsynchronousgenerator Parameter forpower settingVirtual excitation E pVirtual torque M mechVirtual excitation E pVirtual torque M mech DynamicpropertiesVirtual rotating mass(virtual inertial J VISMA)Virtual damping k dVirtual rotating mass(virtual inertial J VISMA)Virtual damping k d Low-pass filter Not necessaryNecessary for themeasurement of thephase currents Island modePossible withextending filtercapacitorsFrequency and voltagecontroller arenecessary for a stablelong-term island gridPossible withouthardwarereconfigurationFrequency andvoltage controller arenecessary for a stablelong-term island grid7.ConclusionsThis paper presents a new method to implemente the VISMA on the PWM controlled inverter by using a current-to-votage model. A comparison of this new method with VISMA-Method 1 by using a voltage-to-current model on the hysteresis controlled inverter has been performed by simulation results. It has been proved that the VISMA-Method 2 is able to behave almost the same static and dynamic properties such as flexible power setting, energetic reproducing the virtual rotating mass and virtual damping in a parallel operation with the public grid as the VISMA-Method 1.Both VISMA-Methods can be operated under an island mode. The VISMA-Method 2 can achieve a better voltage quality compared to the VISMA-Method 1, which needs larger capacitors in order to having the same voltage quality. For building a stable island grid the frequency and voltage controller should be applied in both VISMA-Methods.Considering the widely applied PWM controlled invertes in the current market, the VISMA-Method 2 is tended to be more easily utilized.References[1] R. Hesse, D. Turschner, H.-P. Beck, Die virtuelleSynchronmaschine, VDE Verlag Berlin, Etz Elektrotechnik + Automation S2/2007, pp. 38-44.[2] R. Hesse, H.-P. Beck: Virtual Synchronous Machine,Proceeding, 9th International Conference on Electrical Power Quality and Utilisation, Barcelona (Spain), 2009.[3] Y. Chen , R. Hesse, D. Turschner, H.-P. Beck, DynamicProperties of the Virtual Synchronous Machine (VISMA), in Proc. ICREPQ’11, Las Palmas (Spain), 2011.[4] J. G. Slootweg, W. L. Kling, “Impacts of distributedgeneration on power system transient stability”, PowerEngineering Society Summer Meeting, 2002 IEEE, Vol.: 2, 21-25 July 2002, Pages:862 - 867 vol.2[5] Y. Chen, R. Hesse, D. Turschner, H-P. Beck, Improving theGrid Quality by Using Virtual Synchronous Machine, inProc. PowerEng 2011, Málaga (Spain), 2011.。

DescriptionThe Spartan is a positive mode, tongue operated guard locking interlock switch that locks a machine guard closed until power is isolated and ensures that it remains isolated while the guard is open. It is available in two contact configurations: two safety (N.C.) contacts and one auxiliary (N.O.) contact or three safety (N.C.) contacts. The Spartan head has two entry slots and it can be rotated to provide four actuator entry points. A blanking plug is provided to seal the unused slot.The guard may only be opened when a signal is applied to the Spartan’s internal solenoid which releases the lock mechanism. Therefore the Spartan is ideal for machines which do not stop immediately or where premature interruption of the machine could cause damage to tooling and components or cause an additional hazard.The locking mechanism withstands forces up to of 1200N (270lbs.) and an LED provides visual indication of switch status.A catch kit with actuator alignment is also supplied to relieve stress on the locking solenoid and to protect the unit from actuator damage due to poor guard alignment. Manual release points with security screws or special key allow the locked Spartan to be released in the event of total power failure on a machine.Features•Power to release•Lid mounted status indication•High locking force—1200N (270lbs.)• 2 N.C. & 1 N.O. or 3 N.C.•Rotatable head: 4 possible key entry slotsTypical ApplicationsNote: Lift-off guards require good alignment when usingtongue actuated interlock switches.IMPORTANT: It must not be possible to lift the guardwithout actuating the interlock. An interlock on either sidemay be required.Specifications➊Conductive pollution occurs, or dry, non conductive pollution occurs which becomes conductive due to condensation.Standards EN954-1, ISO13849-1, IEC/EN60204-1,NFPA79, EN1088, ISO14119, IEC/EN60947-5-1, ANSI B11.19, AS4024.1 Category Cat. 1 Device per EN954-1Dual channel interlocks suitable forCat. 3 or 4 systemsApprovals CE marked for all applicable directives,cULus and TUV NordSafety Contact 2 N.C. or 3 N.C. direct opening action Utilization Cat.AC (Ue)(le)DCAC 15500V 250V 100V1A 2A 5A250V/0.5A 24V/2AMaximum Switched Current/Volt/Load500V/500VAThermal Current (lth)10AMin Current5V 5mA DCSafety Contact Gap>2mmRtd. Insulation Voltage500VRtd. Impulse withstand Volt2500VAuxiliary Contacts 1 N.O.Pollution Degree ➊3Max Actuation Speed160mm/second (6.3 in/sec)Max Actuation Frequency 1 cycle/secondCase Material UL Approved glass filled polyester Actuator Material Stainless steelProtection IP 67Conduit Entry 1 x M20 or quick disconnect style Operating T emperature-20°C to 60°C (-4°F to +140°F)Fixing 2 x M5Mounting Any positionMechanical Life1,000,000 operationsElectrical Life1,000,000 operationsWeight260g (0.57 lb)Colour RedMax Holding Force1200N (270lbs)Min Operating Radius175mm (6.9in)LED Indication Solenoid monitor LEDPower Supply24V AC/DC, 110V AC, 230V AC(solenoid)Solenoid Power Typically 7W 100% EDProduct SelectionAccessoriesActuatorSolenoid Voltage ContactsCatalogue NumberSafety Aux.M20 Conduit M20 Conduit/1/2in Adaptor Quick Disconnect Standard 24 V AC/DC2 N.C. 1 N.O.440G-S3*******G-S3*******G-S360583 N.C.—440G-S3*******G-S3*******G-S3******* V AC/DC2 N.C. 1 N.O.440G-S3*******G-S3*******G-S360603 N.C.--440G-S3*******G-S3*******G-S3*******V AC/DC2 N.C. 1 N.O.440G-S3*******G-S3*******G-S360623 N.C.—440G-S36011440G-S36049440G-S36063Mating cable 2m (6.5ft). See page 15-13 for details and additional lengths.889M-F12X9AE-2DescriptionFor Dimensions refer to pageCatalogue NumberReplacement Actuator with CatchRetainer and Guide14-4440G-A36050Emergency Override 14-4440G-A36026Approximate Dimensions—mm (inches)Dimensions are not intended to be used for installation purposes.Typical Wiring Diagrams2 N.C. + 1 N.O.Actuator withdrawal distancefrom full insertion3 N.C.Application Details。

褪黑素欧盟标准
褪黑素是一种由松果体分泌的激素，它在调节睡眠、免疫系统和生物钟方面扮演着重
要的角色。

随着人们认识到褪黑素的重要性，越来越多的人开始使用它来治疗睡眠障碍和
其他健康问题。

因此，欧盟制定了一系列严格的标准来确保褪黑素的质量和安全性。

欧盟标准规定了褪黑素的纯度、含量和质量控制要求。

为了保证褪黑素的纯度，欧盟
要求所有褪黑素产品必须是由天然的L-色氨酸通过化学和生物合成工艺制备而成。

此外，欧盟还规定了褪黑素产品的最低纯度要求，即产品中必须含有99%以上的褪黑素。

欧盟标准还要求褪黑素产品必须具备相应的质量控制措施。

这些措施包括严格的原材
料筛选、生产过程控制和质量检测等。

其中，生产过程控制是非常重要的一项措施，它能
够确保每一个批次的产品都符合标准要求。

此外，欧盟还规定了褪黑素产品的包装和储存
要求，以确保产品的稳定性和安全性。

欧盟标准还要求褪黑素产品必须被正确标识和标示。

产品标识和标示应该包括产品生
产商的名称和地址、产品名称、批号、含量、使用方法和预期效果等信息。

这些信息能够
让使用者更好地了解产品，并且在使用过程中更加安全。

总之，欧盟标准为褪黑素产品的质量和安全提供了保障。

这些标准确保了产品的纯度、含量和质量控制要求，同时还要求产品被正确标识和标示。

对于那些寻求使用褪黑素来改
善睡眠质量和解决其他健康问题的人来说，这些标准是非常重要的，因为它们确保了他们
所购买的产品是安全和有效的。