HCPL-2502-020中文资料

HCPL-0452-000E AVAGOHCPL-0452-300E AVAGOHCPL-0452-500E AVAGOHCPL-0453-000E AVAGOHCPL-0453-300E AVAGOHCPL-0453-500E AVAGOHCPL-0454-000E AVAGOHCPL-0454-300E AVAGOHCPL-0454-500E AVAGOHCPL-0466-000E AVAGOHCPL-0466-300E AVAGOHCPL-0466-500E AVAGOHCPL-0500-000E AVAGOHCPL-0500-300E AVAGOHCPL-0500-500E AVAGOHCPL-0501-000E AVAGOHCPL-0501-300E AVAGOHCPL-0501-500E AVAGOHCPL-050L-000E AVAGOHCPL-050L-300E AVAGOHCPL-050L-500E AVAGOHCPL-0530-000E AVAGOHCPL-0530-300E AVAGOHCPL-0530-500E AVAGOHCPL-0531-000E AVAGOHCPL-0531-300E AVAGOHCPL-0531-500E AVAGOHCPL-0534-000E AVAGOHCPL-0534-300E AVAGO SN74AHC541DW TIHCPL-0534-500E AVAGO SN74AHC573N TIHCPL-053L-000E AVAGO SN74HC125DBR TIHCPL-053L-300E AVAGO SN74HC148N TIHCPL-053L-500E AVAGO SN74HC373DWR TIHCPL-0601-000E AVAGO SN74LS612N TIHCPL-0601-300E AVAGO SN74LV373APWR TIHCPL-0601-500E AVAGO SN74LVC245APWR TIHCPL-060L-000E AVAGO SN74LVC257APWR TIHCPL-060L-300E AVAGO SN74LVC573APWR TIHCPL-060L-500E AVAGO SNJ5410W TIHCPL-0611-000E AVAGO SNJ5420W TIHCPL-0611-300E AVAGO SNJ5450W TIHCPL-0611-500E AVAGO SNJ5474W TIHCPL-061A-000E AVAGO SNJ5483AW TIHCPL-061A-300E AVAGO SNJ54H102W TIHCPL-061A-500E AVAGO SNJ54LS08W TIHCPL-061N-000E AVAGO SNJ54LS123J TIHCPL-061N-300E AVAGO SNJ54LS279W TIHCPL-061N-500E AVAGO SNJ54LS86W TIHCPL-0630-000E AVAGO SPX1585AU-2.5SPHCPL-0630-300E AVAGO SPX1585AU-3.3SPHCPL-0630-500E AVAGO SRFIC08K40R2MOTOROLA HCPL-0631-000E AVAGO SSM2166SZ ADI HCPL-0631-300E AVAGO SSM2250RU-REEL ADI HCPL-0631-500E AVAGO SST39SF010-70-4C-NH sst HCPL-063A-000E AVAGO SST39VF010-70-4C-NHE SST HCPL-063A-300E AVAGO SST39VF800A-70-4C-EK SST HCPL-063A-500E AVAGO SST39VF800A-70-4C-EK SST HCPL-063L-000E AVAGO STAC9766T SIGMATEL HCPL-063L-300E AVAGO STC809JEUR-T STC HCPL-063L-500E AVAGO STC809LEUR-T STC HCPL-063N-000E AVAGO STC809MEUR-T STC HCPL-063N-300E AVAGO STC809REUR-T STC HCPL-063N-500E AVAGO STC809SEUR-T STC HCPL-0661-000E AVAGO STC809TEUR-T STC HCPL-0661-300E AVAGO STC810JEUR-T STC HCPL-0661-500E AVAGO STC810LEUR-T STC HCPL-0700-000E AVAGO STC810MEUR-T STC HCPL-0700-300E AVAGO STC810REUR-T STC HCPL-0700-500E AVAGO STC810SEUR-T STC HCPL-0701-000E AVAGO STC810TEUR-T STC HCPL-0701-300E AVAGO STC811JEUS-T STC HCPL-0701-500E AVAGO STC811LEUS-T STC HCPL-0708-000E AVAGO STC811MEUS-T STC HCPL-0708-300E AVAGO STC811REUS-T STC HCPL-0708-500E AVAGO STC811SEUS-T STC HCPL-070A-000E AVAGO STC811TEUS-T STC HCPL-070A-300E AVAGO STC812JEUS-T STC HCPL-070A-500E AVAGO STC812LEUS-T STC HCPL-070L-000E AVAGO STC812MEUS-T STC HCPL-070L-300E AVAGO STC812REUS-T STC HCPL-070L-500E AVAGO STC812SEUS-T STC HCPL-0710-000E AVAGO STC812TEUS-T STC HCPL-0710-300E AVAGO STM809JWX6F STHCPL-0710-500E AVAGO STM809LWX6F STHCPL-0720-000E AVAGO STM809MWX6F STHCPL-0720-300E AVAGO STM809RWX6F STHCPL-0720-500E AVAGO STM809SWX6F STHCPL-0721-000E AVAGO STM809TWX6F STHCPL-0721-300E AVAGO STM810JWX6F STHCPL-0721-500E AVAGO STM810LWX6F STHCPL-0723-000E AVAGO STM810MWX6F STHCPL-0723-300E AVAGO STM810RWX6F STHCPL-0723-500E AVAGO STM810SWX6F STHCPL-0730-000E AVAGO STM810TWX6F STHCPL-0730-300E AVAGO STM811JW16F STHCPL-0730-500E AVAGO STM811LW16F STHCPL-0731-000E AVAGO STM811MW16F STHCPL-0731-300E AVAGO STM811RW16F STHCPL-0731-500E AVAGO STM811SW16F STHCPL-0738-000E AVAGO STM811TW16F STHCPL-0738-300E AVAGO STM812JW16F STHCPL-0738-500E AVAGO STM812LW16F STHCPL-073A-000E AVAGO STM812MW16F STHCPL-073A-300E AVAGO STM812RW16F STHCPL-073A-500E AVAGO STM812SW16F STHCPL-073L-000E AVAGOHCPL-073L-300E AVAGOHCPL-073L-500E AVAGOHCPL-0900-000E AVAGOHCPL-0900-300E AVAGOHCPL-0900-500E AVAGOHCPL-090J-000E AVAGOHCPL-090J-300E AVAGOHCPL-090J-500E AVAGOHCPL-091J-000E AVAGOHCPL-091J-300E AVAGOHCPL-091J-500E AVAGOHCPL-092J-000E AVAGOHCPL-092J-300E AVAGOHCPL-092J-500E AVAGOHCPL-0930-000E AVAGOHCPL-0930-300E AVAGOHCPL-0930-500E AVAGOHCPL-0931-000E AVAGOHCPL-0931-300E AVAGOHCPL-0931-500E AVAGOHCPL-181-000E AVAGOHCPL-181-00AE AVAGO TCM810TENB713MICROCHIP HCPL-181-00BE AVAGO TCM811JERCTR MICROCHIP HCPL-181-00CE AVAGO TCM811LERCTR MICROCHIP HCPL-181-00DE AVAGO TCM811MERCTR MICROCHIP HCPL-181-060E AVAGO TCM811RERCTR MICROCHIP HCPL-181-06AE AVAGO TCM811SERCTR MICROCHIP HCPL-181-06BE AVAGO TCM811TERCTR MICROCHIP HCPL-181-06CE AVAGO TCM812JERCTR MICROCHIP HCPL-181-06DE AVAGO TCM812LERCTR MICROCHIP HCPL2200-000E AVAGO TCM812MERCTR MICROCHIP HCPL-2200-000E AVAGO TCM812RERCTR MICROCHIP HCPL2200-300E AVAGO TCM812SERCTR MICROCHIP HCPL-2200-300E AVAGO TCM812TERCTR MICROCHIP HCPL2200-500E AVAGO TD1605C wearnes HCPL-2200-500E AVAGO TFDU2201-TR1VISHAY HCPL2201-000E AVAGO TFDU2201-TR3VISHAYHCPL-2201-000E AVAGO TFDU4100-TR3VISHAY HCPL2201-300E AVAGO TFDU4100-TT3VISHAY HCPL-2201-300E AVAGO TFDU4201-TR1VISHAY HCPL2201-500E AVAGO TFDU4201-TR3VISHAY HCPL-2201-500E AVAGO TFDU4202-TR1VISHAY HCPL-2202-000E AVAGO TFDU4202-TR3VISHAY HCPL-2202-300E AVAGO TFDU4203-TR1VISHAY HCPL-2202-500E AVAGO TFDU4203-TR3VISHAY HCPL-2211-000E AVAGO TISP4350H3BJR BOURNS HCPL-2211-300E AVAGO TJA1020T PHI HCPL-2211-500E AVAGO TJA1040TD PHI HCPL2212-000E AVAGO TL062IDR TI HCPL-2212-000E AVAGO TL064IDR TI HCPL2212-300E AVAGO TL071IDR TI HCPL-2212-300E AVAGO TL072IDR TI HCPL2212-500E AVAGO TL074IDR TI HCPL-2212-500E AVAGO TL081IP TIHCPL-2219-000E AVAGO TL082IDR TI HCPL-2219-300E AVAGO TL084IDR TI HCPL-2219-500E AVAGO TL431AIDR TIHCPL2231-000E AVAGO TL431BCLP TIHCPL-2231-000E AVAGO TL431IPK TIHCPL2231-300E AVAGO TLC0820AIDWR TIHCPL-2231-300E AVAGO TLC2254CD TIHCPL2231-500E AVAGO TLC27L2IDR TI HCPL-2231-500E AVAGO TLC3702CDR TIHCPL2232-000E AVAGO TLC542IDW TIHCPL-2232-000E AVAGO TLC5615CDR TIHCPL2232-300E AVAGO TLC5615IDR TIHCPL-2232-300E AVAGO TLE2062CDR TIHCPL-2232-500E AVAGO TLE2062IDR TIHCPL-2300-000E AVAGO TLV2211CDBVR TIHCPL-2300-300E AVAGO TLV2211IDBVR TIHCPL-2300-500E AVAGO TLV2231CDBVR TIHCPL-2400-000E AVAGO TLV2451IDBVR TIHCPL-2400-300E AVAGO TLV2471CDBVR TIHCPL-2400-500E AVAGO TLV2711IDBVR TIHCPL-2430-000E AVAGO TLV27L1IDBVR TIHCPL-2430-300E AVAGO TLV431AIDR TI HCPL-2430-500E AVAGO TMP82C79M-2TOSHIBA HCPL-2502-000E AVAGO TOIM4232-TR1VISHAY HCPL-2502-300E AVAGO TPA3008D2PHPRG4TI HCPL-2502-500E AVAGO TPS61042DRBR TI HCPL-2503-000E AVAGO UC2833N TI HCPL-2503-300E AVAGO UC2846DW TIHCPL-2503-500E AVAGO UC2846N TIHCPL-2530-000E AVAGO UC3833N TI HCPL-2530-300E AVAGO UC3846DWTR TIHCPL-2530-500E AVAGO UC3846N TIHCPL-2531-000E AVAGO UCC2818AADTRG4TI HCPL-2531-300E AVAGO UCC2818ADG4TI HCPL-2531-500E AVAGO UCC2818DG4TI HCPL-2601-000E AVAGO UCC2818DTRG4TI HCPL-2601-300E AVAGO UCC2895DWR TI HCPL-2601-500E AVAGO UCC3895DWR TI HCPL-2602-000E AVAGO UPC2758T-E3NECHCPL-2602-300E AVAGO uPD6453GT101NECHCPL-2602-500E AVAGO uPD6464AGT101NECHCPL-260L-000E AVAGO W78LE516-24WINBOND HCPL-260L-300E AVAGO W78LE516P-24WINBOND HCPL-260L-500E AVAGO W78LE52P-24WINBOND HCPL-2611-000E AVAGO W89C92WINBOND HCPL-2611-300E AVAGO X1227S8I XICOR HCPL-2611-500E AVAGO X25650S8I2.5XICOR HCPL-2612-000E AVAGO XEL22MICREL HCPL-2612-300E AVAGO XEL22L MICREL HCPL-2612-500E AVAGO XEL23MICREL HCPL-261A-000E AVAGO XEL23L MICREL HCPL-261A-300E AVAGO XPC850DSLZT50BU MOTOROLA HCPL-261A-500E AVAGO XR17C158CV MOTOROLA HCPL-261N-000E AVAGO TPS62220DDCR TIHCPL-261N-300E AVAGO TPS62222DDCR TIHCPL-261N-500E AVAGO HCPL-J314-000E AVAGO HCPL-2630-000E AVAGO HCPL-J314-300E AVAGO HCPL-2630-300E AVAGO HCPL-J314-500E AVAGO HCPL-2630-500E AVAGO HCPL-7860-300E AVAGO HCPL-2631-000E AVAGO HCPL-7860-500E AVAGO HCPL-2631-300E AVAGO MGA-87563-BLKG AVAGO HCPL-2631-500E AVAGO MGA-87563-TR1G AVAGO HCPL-263A-000E AVAGO MGA-87563-TR2G AVAGO HCPL-263A-300E AVAGO HLMP-6000AVAGO HCPL-263A-500E AVAGO OP42GSZ ADI HCPL-263N-000E AVAGO TLV5620IDR TI HCPL-263N-300E AVAGO DS1306EN+T DALLAS HCPL-263N-500E AVAGO TMS320F206PZA TI HCPL-2730-000E AVAGO AD8323ARUZ-REEL ADI HCPL-2730-300E AVAGO HCPL-3101-000E AVAGO HCPL-2730-500E AVAGO HCPL-3101-300E AVAGO HCPL-2731-000E AVAGO HCPL-3101-500E AVAGO HCPL-2731-300E AVAGO DS1338Z-33+DALLAS HCPL-2731-500E AVAGO DS1817R-10+TR DALLAS HCPL-273L-000E AVAGO HSMS-2825-TR2G AVAGO HCPL-273L-300E AVAGO HSMS-2825-TR1G AVAGO HCPL-273L-500E AVAGO HSMS-282C-TR1G AVAGO HCPL-3020-000E AVAGO HSMS-282C-BLKG AVAGO HCPL-3020-300E AVAGO HSMS-282C-TR2G AVAGOHCPL-3020-500E AVAGO HSMS-2820-TR1G AVAGO HCPL-3100-000E AVAGO HSMS-2820-BLKG AVAGO HCPL-3100-300E AVAGO HSMS-2820-TR2G AVAGO HCPL-3120-000E AVAGO HSMS-282F-TR1G AVAGO HCPL-3120-300E AVAGO HSMS-282F-BLKG AVAGO HCPL-3120-500E AVAGO HSMS-282F-TR2G AVAGO HCPL-3140-000E AVAGO AD712SQ/883B ADI HCPL-3140-300E AVAGO OPA2277PA TI HCPL-3140-500E AVAGO OPA2277UA TI HCPL-314J-000E AVAGO LM2675MX-ADJ NS HCPL-314J-300E AVAGO LTC1265CS Linear HCPL-314J-500E AVAGO LTC1265IS Linear HCPL-3150-000E AVAGO HSMS-2805-TR1G AVAGO HCPL-3150-300E AVAGO HSMS-2805-TR2G AVAGO HCPL-3150-500E AVAGO HSMP-3894-TR1G AVAGO HCPL-316J-000E AVAGO HSMP-3894-TR2G AVAGO HCPL-316J-300E AVAGO AT89C4051-24PU ATMEL HCPL-316J-500E AVAGO AT89C55WD-24JU ATMEL HCPL-3180-000E AVAGO MAX487ESA+T MAXIM HCPL-3180-300E AVAGO MAX487EEPA+MAXIM HCPL-3180-500E AVAGO MSP430F149IPMR TI HCPL-3700-000E AVAGO TPS65021RHAR TI HCPL-3700-300E AVAGO SSM2211SZ ADI HCPL-3700-500E AVAGO TLC3578IDW TI HCPL-3760-000E AVAGO AD9048SQ/883B ADI HCPL-3760-300E AVAGO AD9048TQ/883B ADI HCPL-3760-500E AVAGO AT89S52-24JU ATMEL HCPL-4100-000E AVAGO XC9536XL-7VQ64C XILINX HCPL-4100-300E AVAGO XTR101BG TI HCPL-4100-500E AVAGO MSC1210Y4PAGT TI HCPL-4200-000E AVAGO MSC1210Y4PAGR TI HCPL-4200-300E AVAGO ADS1178IPAPT TI HCPL-4200-500E AVAGO ACNW3190-300E AVAGO HCPL-4502-000E AVAGO MSP430F2418TPNR TI HCPL-4502-300E AVAGO MSP430F2418TPMR TI HCPL-4502-500E AVAGO XC95288XL-7TQ144C XILINX HCPL-4503-000E AVAGO TPS5100IPWR TI HCPL-4503-300E AVAGO EPM7128AETC144-10ALTERA HCPL-4503-500E AVAGO TMS320DM6446AZWTA TI HCPL-4504-000E AVAGO TMS320DM6446ZWT TI HCPL-4504-300E AVAGO UC3906N TI HCPL-4504-500E AVAGO UC3906DW TI HCPL-4506-000E AVAGO TPS54614PWPR TI HCPL-4506-300E AVAGO HCPL-0600-500E AVAGO HCPL-4506-500E AVAGO HEDS-9701#C54AVAGO HCPL-4534-000E AVAGO TLC04CP TI HCPL-4534-300E AVAGO X9313WSZ-3T1INTERSIL HCPL-4534-500E AVAGO TMS320LF2402APGA TIHCPL-4562-000E AVAGO TMS320LF2406APZA TI HCPL-4562-300E AVAGO AD9910BSVZ ADI HCPL-4562-500E AVAGO AD9957BSVZ ADI HCPL-4661-000E AVAGO TLV320AIC33IRGZ TI HCPL-4661-300E AVAGO TLV320AIC33IZQER TI HCPL-4661-500E AVAGO TPS54616PWPR TI HCPL-4731-000E AVAGO OPA551PA TI HCPL-4731-300E AVAGO DS1813R-15+DALLAS HCPL-4731-500E AVAGO TPS7333QDR TI HCPL-7510-000E AVAGO OPA277UA TI HCPL-7510-300E AVAGO LM1877MX-9NS HCPL-7510-500E AVAGO ISO7221BDR TI HCPL-7520-000E AVAGO TL16C550CIPTR TI HCPL-7520-300E AVAGO MAX9324EUP+MAXIM HCPL-7520-500E AVAGO MAX1706EEE-T MAXIM HCPL-7560-000E AVAGO TPS75733KTTR TI HCPL-7560-300E AVAGO LM2674MX-ADJ NS HCPL-7560-500E AVAGO ADS8321EB TI HCPL-7611-000E AVAGO ADS8320EB TI HCPL-7611-300E AVAGO W29C040T-90B WINBOND HCPL-7611-500E AVAGO ISO124U TI HCPL-7710-000E AVAGO FM25L04B-GTR RAMTRON HCPL-7710-300E AVAGO TLE2084CN TI HCPL-7710-500E AVAGO TL317CDR TI HCPL-7720-000E AVAGO MAX354CPE+MAXIM HCPL-7720-300E AVAGO MAX354EPE+MAXIM HCPL-7720-500E AVAGO DEI0429-WMB DEI HCPL-7721-000E AVAGO AT91SAM7SE512-AU atmel HCPL-7721-300E AVAGO EL1881CSZ-T7INTERSIL HCPL-7721-500E AVAGO SN74ACT2440FNR TI HCPL-7723-000E AVAGO MT4LC8M8C2P-5MICRON HCPL-7723-300E AVAGOHCPL-7723-500E AVAGOHCPL-7800-000E AVAGOHCPL-7800-300E AVAGOHCPL-7800-500E AVAGOHCPL-7800A-000E AVAGOHCPL-7800A-300E AVAGOHCPL-7800A-500E AVAGOHCPL-7840-000E AVAGOHCPL-7840-300E AVAGOHCPL-7840-500E AVAGOHCPL786J-000E AVAGOHCPL-786J-000E AVAGOHCPL786J-300E AVAGOHCPL-786J-300E AVAGOHCPL786J-500E AVAGOHCPL-786J-500E AVAGOHCPL788J-000E AVAGOHCPL-788J-000E AVAGOHCPL788J-300E AVAGOHCPL-788J-300E AVAGOHCPL788J-500E AVAGOHCPL-788J-500EHCPL-817-000EHCPL-817-00AEHCPL-817-00BEHCPL-817-00CEHCPL-817-00DEHCPL-817-00LEHCPL-817-060EHCPL-817-06AEHCPL-817-06BEHCPL-817-06CEHCPL-817-06DEHCPL-817-06LEHCPL-817-300EHCPL-817-30AEHCPL-817-30BEHCPL-817-30CEHCPL-817-30DEHCPL-817-30LEHCPL-817-360EHCPL-817-36AEHCPL-817-36BEHCPL-817-36CEHCPL-817-36DEHCPL-817-36LEHCPL-817-500EHCPL-817-50AEHCPL-817-50BEHCPL-817-50CEHCPL-817-50DEHCPL-817-50LEHCPL-817-560EHCPL-817-56AEHCPL-817-56BEHCPL-817-56CEHCPL-817-56DEHCPL-817-56LEHCPL-9000-000EHCPL-9000-300EHCPL-9000-500EHCPL-902J-000EHCPL-902J-300E AVAGO TLV320AIC3204IRHBR TI HCPL-902J-500E AVAGO TLV5625CDR TIHCPL-J312-000E AVAGO TLV5625IDR TIHCPL-J312-300E AVAGO TLV320AIC3104IRHBT TIHCPL-J312-500E AVAGO TLV320AIC3104IRHBR TIHCPL-J456-000E AVAGO AT45DB041D-SU ATMEL HCPL-J456-300E AVAGO MAX6657MSA+T MAXIM HCPL-J456-500E AVAGO HCPL-J454-000E AVAGO HCPL-M453-000E AVAGO HCPL-J454-300E AVAGO HCPL-M453-300E AVAGO HCPL-J454-400E AVAGO HCPL-M453-500E AVAGO HCPL-J454-500E AVAGO HCPL-M454-000E AVAGO HCPL-J454-600E AVAGO HCPL-M454-300E AVAGO TC7660IJA MICROCHIP HCPL-M454-500E AVAGO TC7660MJA MICROCHIP HCPL-M456-000E AVAGO ADT7460ARQZ ADIHCPL-M456-300E AVAGO ADSP-21065LKCA264ADIHCPL-M456-500E AVAGO ADSP-21065LKCAZ264ADI HCPL-M600-000E AVAGO AD7859ASZ ADI HCPL-M600-300E AVAGO MJD45H11G ONHCPL-M600-500E AVAGO TPD3E001DRLR TIHCPL-M601-000E AVAGO XTR116U TIHCPL-M601-300E AVAGO DS1233-5+DALLAS HCPL-M601-500E AVAGO TRU050GALGA32.0000/16.0000V ectron HCPL-M611-000E AVAGO TRU050GACCA28.7040/14.3520V ectron HCPL-M611-300E AVAGO AD9516-3BCPZ ADI HCPL-M611-500E AVAGO REF3125AIDBZT TIHCPL-M700-000E AVAGO REF3125AIDBZR TIHCPL-M700-300E AVAGO AD8592ARMZ ADI HCPL-M700-500E AVAGO QCPL-034H-500E AVAGOHD6413079F18HIT AD9865BCPZ ADI HDMP1636A AVAGO QCPL-312H-500E AVAGO HDMP-1636A AVAGO M74VHC1G135DFT1G ONHDMP-1637A AVAGO HSMD-A100-J00J1AVAGO HDMP1638AVAGO LT1587CT LTHDMP-1638AVAGO AD827JRZ-16ADI HEDS9710-R50AVAGO HSMP-389F-BLKG AVAGO HEDS-9710-R50AVAGO HSMP-389F-TR1G AVAGO HEL22MICREL HSMP-389F-TR2G AVAGO HEL23MICREL XC3064A-7PC84C XILINX HFBR-1414Z AVAGO XC3064A-7PC84I XILINX HFBR-1414TZ AVAGO Si7703EDN-T1-E3VISHAY HFBR-1521Z AVAGO Si7703EDN-T1-GE3VISHAYT-1521Z AVAGO Si7703EDN-T1-GE3ADIT-1521ETZ AVAGO AD605ARZ ADI HFBR-1521ETZ AVAGO MACH110-15JC AMDT-1522Z AVAGO MACH210-20JC AMDT-1522ETZ AVAGO LTC4213IDDB LINEAR HFBR-1522ETZ AVAGO DS1233-15+DALLAS HFBR1522Z AVAGO LTC3412EFE LINEAR HFBR-1522Z AVAGO MAX513ESD+T MAXIMHFBR1523Z AVAGO MAX3681EAG+MAXIM HFBR-1523Z AVAGO ICS1893CKILF IDT HFBR1528Z AVAGO TMS32C6416DGLZA5E0TI HFBR-1528Z AVAGO TMS32C6416EGLZ5E0TI HFBR-1531Z AVAGO TMS32C6416EGLZ6E3TI HFBR-1531ETZ AVAGO TMS32C6416EGLZ7E3TI HFBR-2531ETZ AVAGO TMS32C6416EGLZA5E0TI 1531ETZ AVAGO TMS32C6416EGLZA6E3TI 2531ETZ AVAGO AD829JRZ ADI HFBR1532Z AVAGO MAX14830ETM+MAXIM HFBR-1532Z AVAGO MX69GL128EAXGW-90G MXIC HFBR-1532ETZ AVAGO AD7811YRUZ ADI HFBR1533Z AVAGO TPS76318DBVR TI HFBR-1533Z AVAGO ADMP421ACEZ ADI HFBR-2412TZHFBR-2412ZHFBR2416TZHFBR-2416TZHFBR-2521Z AVAGO LT1304CS8Linear R-2521Z AVAGO MAX16801BEUA+T maxim R-2521ETZ AVAGO ACPL-M61L-500E AVAGO HFBR-2521ETZ AVAGO DS26503LN+DALLAS HFBR-2522Z AVAGO MAX9205EAI+T MAXIM R-2522Z AVAGO TMP105YZCT TIR-2522ETZ AVAGO TMP105YZCR TI HFBR-2522ETZ AVAGO AD5821BCBZ ADI HFBR-2523Z AVAGO PM5347-RI PMC HFBR-2528Z AVAGO PM73121-RI PMC HFBR-2531Z AVAGO TPA4411RTJT TI HFBR-2532Z AVAGO TPA4411RTJR TI HFBR-2532ETZ AVAGO LTC1438CG-ADJ Linear HFBR-2533Z AVAGO LTC1438IG-ADJ Linear HFBR-4501Z AVAGO DS1318E+DALLAS HFBR-4503Z AVAGO TMS320DM643AGDK5TI HFBR-4506Z AVAGO ACPL-M75L-000E AVAGO HFBR-4511Z AVAGO ACPL-M75L-060E AVAGO HFBR-4513Z AVAGO ACPL-M75L-500E AVAGO HFBR-4516Z AVAGO ACPL-M75L-560E AVAGO HFBR-4525Z AVAGO ACPL-T350-000E AVAGO HFBR-4526Z AVAGO ACPL-T350-060E AVAGO HFBR-4531Z AVAGO ACPL-T350-300E AVAGO HFBR-4532Z AVAGO ACPL-T350-360E AVAGO HFBR-4533Z AVAGO ACPL-T350-500E AVAGO HFBR-4535Z AVAGO ACPL-T350-560E AVAGO HFBR-4593Z AVAGO ADXRS620BBGZ ADI HFBR-4597Z AVAGO LT1521CS8Linear HFBR-EUD100Z AVAGO LT1521CS8-3.3Linear HFBR-EUD500Z AVAGO LT1521IS8LinearHFBR-EUS100Z AVAGO LT1521IS8-3.3Linear HFBR-EUS500Z AVAGO MAX6835VXSD3+T MAXIM HFBR-RUD100Z AVAGO AD9059BRSZ ADI HFBR-RUD500Z AVAGO HFBR-4515Z AVAGO HFBR-RUS100Z AVAGO HFBR-57E0PZ AVAGO HFBR-RUS500Z AVAGO HFCT-53D5EMZ AVAGO HG88510MITEL HFCT-5611AVAGOHI1-508-5HAR LT1242CS8Linear HI1-509-5HAR LT1242IS8Linear HM628512ALFP-5日立LT1140ACSW LinearHM628512BLFP-5日立AFBR-2419TZ AVAGO HS1101HUMIREL AD7156BCPZ ADIHS6118MACONICS ADP151ACBZ-2.8ADI HSDL-3201#021AVAGO DS1805Z-010+MAXIM HSDL-3201#001AVAGO TLP285-4GB TOSHIBA HSDL-3209-021AVAGO AD421BRZ ADI HSDL-7001#100AVAGO OPA2336PA TI HSDL-7002AVAGO ADUC812BSZ ADI HSMP-3814-BLKG AVAGO STPS6045CW ST HSMP-3814-TR1G AVAGO SG-3030JF EPSON HSMP-3814-TR2G AVAGO MPC8313VRAFFB FREESCAL HSMP-3822-BLKG AVAGO MAX1617AMEE+T maxim HSMP-3822-TR1G AVAGO MCP809M3X-4.63NS HSMP-3822-TR2G AVAGO MCP809M3X-4.38NS HSMP-3823-BLKG AVAGO MCP809M3X-4.00NS HSMP-3823-TR1G AVAGO MCP809M3X-3.08NS HSMP-3823-TR2G AVAGO MCP809M3X-2.93NS HSMP-3824-BLKG AVAGO MCP809M3X-2.63NS HSMP-3824-TR1G AVAGO MCP810M3X-4.63NS HSMP-3824-TR2G AVAGO MCP810M3X-4.38NS HSMP-3832-BLKG AVAGO MCP810M3X-4.00NS HSMP-3832-TR1G AVAGO MCP810M3X-3.08NS HSMP-3832-TR2G AVAGO MCP810M3X-2.93NS HSMP-3860-BLKG AVAGO MCP810M3X-2.63NS HSMP-3860-TR1G AVAGO LT1317BCS8Linear HSMP-3860-TR2G AVAGO LT1317BIS8Linear HSMP-3862-BLKG AVAGO LTC1757A-1EMS8Linear HSMP-3862-TR1G AVAGO ACPL-K342-000E AVAGO HSMP-3862-TR2G AVAGO ACPL-K342-500E AVAGO HSMP-3880-BLKG AVAGO AFBR-57M5APZ AVAGO HSMP-3880-TR1G AVAGO CY7C144AV-25AIT CY HSMP-3880-TR2G AVAGO CY7C144AV-25ACT CY HSMP-3892-BLKG AVAGO CY7C144AV-25AXIT CY HSMP-3892-TR1G AVAGO CY7C144AV-25AXCT CY HSMP-3892-TR2G AVAGO ABA-54563-TR1G AVAGO HSMP-389L-BLKG AVAGO ABA-54563-TR2G AVAGO HSMP-389L-TR1G AVAGO ABA-54563-BLKG AVAGO HSMP-389L-TR2G AVAGO LT1138ACG LinearHSMS-2812-BLKG AVAGO LT1138AIG Linear HSMS-2812-TR1G AVAGO ISL8120IRZ INTERSIL HSMS-2812-TR2G AVAGO ISL8120CRZ INTERSIL HSMS-2817-BLKG AVAGO LTC1421IG-2.5Linear HSMS-2817-TR1G AVAGO LTC1421CG-2.5Linear HSMS-2817-TR2G AVAGO MSC1212Y5PAGT TI HSMS-282K-BLKG AVAGO MSC1212Y5PAGR TI HSMS-282K-TR1G AVAGO TPS7330QDR TI HSMS-282K-TR2G AVAGO ADP3110KRZ ADI HSMS-2850-BLKG AVAGO MAX3263CAG MAXIM HSMS-2850-TR1G AVAGO MAX1729EUB MAXIM HSMS-2850-TR2G AVAGO MAX1651CSA MAXIM HSMS-8202-BLKG AVAGO AD876JR ADI HSMS-8202-TR1G AVAGO MAX1701EEE MAXIM HSMS-8202-TR2G AVAGO Si4201-BMR silicon HT2012-PL SMAR DS12C887+DALLAS HY62256ALT1-70HY LM236DR-2.5TIHY628100BLLG-70HY DS1722U DALLAS HY628100BLLG-70I HY LM7372MRX NSHY628400ALLG-55HY MAX490ESA+T MAXIM HY628400ALLG-70HY HSMS-2822-TR1G AVAGO HY62WT08081E-DG70C HY HSMP-389C-TR1G AVAGO HY62WT08081E-DG70I HY HSMP-389C-BLKG AVAGO ICL232IPE HAR HSMP-389C-TR2G AVAGO ICS8432DY-101ICS MC33375D-3.3R2G ONICS85322AM ICS AFBR-1529Z AVAGO ICS9112M-16ICS AFBR-2529Z AVAGO IDT75K62134S200BB IDT AFBR-1629Z AVAGO ILX139K SONY HSMS-2828-TR1G AVAGO IMP560ESA IMP TPS7101QDR TIIMP809JEUR-T IMP AFBR-57R5APZ AVAGO IMP809LEUR-T IMP UC3875DWPTR TIIMP809MEUR-T IMP ASSR-1510-503E AVAGO IMP809REUR-T IMP ASSR-1510-003E AVAGO IMP809SEUR-T IMP CY7B9514V-AC CYIMP809TEUR-T IMP MAX4450EXK+T MAXIM IMP810JEUR-T IMP SN75976A1DLR TIIMP810LEUR-T IMP ADUC831BSZ ADIIMP810MEUR-T IMP LTC1348IG LINEAR IMP810REUR-T IMP MSA-2111-TR1G AVAGO IMP810SEUR-T IMP DS1621S+T DALLAS IMP810TEUR-T IMP MAX485EESA+T MAXIM IMP811JEUS-T IMP MAX9669ETI+T MAXIM IMP811LEUS-T IMP MSA-0711-TR1G AVAGO IMP811MEUS-T IMP ACPL-P480-500E AVAGO IMP811REUS-T IMP HSMS-2800-TR1G AVAGO IMP811SEUS-T IMP LTC1622IS8LINEAR IMP811TEUS-T IMP MAX2102CWI MAXIMACPL-312T-500E AVAGO X24165S-2.7T1XICOR ACPL-H342-560E AVAGO X84129SI-2.5T1XICOR ACPL-H342-500E AVAGO HCNW4502-500E AVAGO ACPL-H342-060E AVAGO HCNW4502-300E AVAGO ACPL-H342-000E AVAGO AD811ARZ-16ADI ACPL-K63L-500E AVAGO TOCP155TOSHIBA ACPL-K63L-560E AVAGO TOCP200TOSHIBA ACPL-K63L-000E AVAGO HFBR-14E4Z AVAGO AFBR-5803AQZ AVAGO HFBR-24E2Z AVAGO ASSR-4128-502E AVAGO ALM-2412-TR1G AVAGO HSMH-C680AVAGO TLV320DAC23GQER TIWS1403-TR1AVAGO CY2509ZXC-1T CYLST2825-T-SC AGILENT ACPL-312T-300E AVAGO MAX853ESA+T MAXIM MAX3814CHJ+T MAXIM。

有篇关于光耦的小文章推荐你看看：光电耦合器(简称光耦)是开关电源电路中常用的器件。

光电耦合器分为两种：一种为非线性光耦,另一种为线性光耦。

常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。

非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输，不适合于传输模拟量。

线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好，能以线性特性进行隔离控制。

开关电源中常用的光耦是线性光耦。

如果使用非线性光耦，有可能使振荡波形变坏，严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。

由此产生的后果是对彩电，彩显,VCD，DCD等等，将在图像画面上产生干扰。

同时电源带负载能力下降。

在彩电，显示器等开关电源维修中如果光耦损坏，一定要用线性光耦代换。

常用的4脚线性光耦有PC817A--——C。

PC111 TLP521等常用的六脚线性光耦有：TLP632 TLP532 PC614 PC714 PS2031等。

常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的，因为这4种光耦均属于非线性光耦。

以下是目前市场上常见的高速光藕型号：100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL—2503、HCPL—4502、HCPL—2530(双路）、HCPL—2531(双路）10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL—2601、HCPL—2611、HCPL—2630（双路)、HCPL－2631（双路）光耦合器的增益被称为晶体管输出器件的电流传输比（CTR）,其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。

光电晶体管集电极电流与VCE有关，即集电极和发射极之间的电压。

DescriptionThe HCPL-22XX, HCPL-02XX, and HCNW22XX are optical-ly-coupled logic gates. The HCPL-22XX, and HCPL-02XX contain a GaAsP LED while the HCNW22XX contains an AlGaAs LED. The detectors have totem pole output stag-es and optical receiver input stages with built-in Schmitt triggers t o p rovide l ogic-compatible w aveforms, e liminat-ing the need for additional waveshaping.A superior internal shield on the HCPL-2211/12, HCPL-0211, HCPL-2232 and HCNW2211 guarantees common mode transient immunity of 10 kV/µs at a common mode voltage of 1000 volts.Functional DiagramCAUTION: It is advised that normal static precautions be taken in handling and assembly of this component to prevent damage and/or degradation which may be induced by ESD.A 0.1 µF bypass capacitor must be connected between pins 5 and 8.NC ANODE CATHODE NC GNDV CC V O NC HCPL-2201/11HCPL-0201/11HCPL-2201 Functional Diagram NC ANODE CATHODE NC GNDV CC V O NC ANODE 1CATHODE 1CATHODE 2ANODE 2GNDV CC V O1V O2TRUTH TABLE (POSITIVE LOGIC)LED ON OFF V O HIGH LOWHCPL-2201, HCPL-2202, HCPL-2211,HCPL-2212, HCPL-2231, HCPL-2232, HCPL-0201, HCPL-0211, HCNW2201, HCNW2211Very High CMR, Wide V CC Logic Gate OptocouplersData SheetFeatures• 10 kV/µs minimum Common Mode Rejection(CMR) at V CM = 1000 V (HCPL-2211/2212/0211/2232, HCNW2211)• Wide operating V CC range: 4.5 to 20 Volts• 300 ns propagation delay guaranteed over the full temperature range• 5 Mbd typical signal rate• Low input current (1.6 mA to 1.8 mA)• Hysteresis• Totem pole output (no pullup resistor required)• Available in 8-Pin DIP , SOIC-8, widebody packages • Guaranteed performance from -40°C to 85°C • Safety approval– UL recognized -3750 V rms for 1 minute (5000 V rms for 1 minute for HCNW22XX) per UL1577– CSAapproved– IEC/EN/DIN EN 60747-5-2 approved with V IORM = 630 V peak (HCPL-2211/2212 Option 060 only) and V IORM = 1414 V peak (HCNW22XX only)• MIL-PRF-38534 hermetic version available (HCPL-52XX/62XX)Applications• Isolation of high speed logic systems• Computer-peripheral interfaces • Microprocessor system interfaces • Ground loop elimination• Pulse transformer replacement • High speed line receiver • Power control systemsSchematicHCPL-2201 SchematicHCPL-2201/02/11/12HCPL-0201/11HCNW2201/11V CCV OGNDV V CCV O1HCPL-2231/32V V O2GNDThe electrical and switching characteristics of the HCPL-22XX, HCPL-02XX and HCNW22XX are guaranteed from -40°C to +85°C and a V CC from 4.5 volts to 20 volts. Low I F and wide V CC range allow compatibility with TTL, LSTTL,and CMOS logic and result in lower power consumption compared to other high speed couplers. Logic signals are transmitted with a typical propagation delay of 150 ns.Small- Widebody Minimum CMR I nput 8-Pin DIP (300 Mil) Outline SO-8 (400 Mil) Hermetic On- Single Dual Single Single Single and dV/dt Current Channel Channel Channel Channel Dual Channel (V/µs) V CM (V) (mA) Package Package Package Package Packages1,000 50 1.6 HCPL-2200[1,2] HCPL-0201HCNW2201HCPL-2201 HCPL-2202 1.8 HCPL-22312,500 400 1.6 HCPL-2219[1,2] 5,000[3] 300[3] 1.6 HCPL-2211 HCPL-0211HCNW2211HCPL-2212 1,000 50 2.0 HCPL-52XX [2]HCPL-62XX [2]Notes:1. HCPL-2200/2219 devices include output enable/disable function.2. Technical data for the HCPL-2200/2219, HCPL-52XX and HCPL-62XX are on separate Avago publications.3. Minimum CMR of 10 kV/µs with V CM = 1000 V can be achieved with input current, I F , of 5 mA.Selection GuideOrdering InformationHCPL-2201, HCPL-2202, HCPL-2211, HCPL-2212, HCPL-2231, HCPL-2232, HCPL-0201, HCPL-0211 are UL Recognized with 3750 Vrms for 1 minute per UL1577.HCNW2201 and HCNW2211 are UL Recognized with 5000 Vrms for 1 minute per UL1577.All devices listed above are approved under CSA Component Acceptance Notice #5, File CA 88324.Part numberOptionPackageSurfaceMountGullWingTape &ReelUL 5000Vrms/ 1MinuteratingIEC/EN/DIN EN60747-5-2Quantity RoHSCompliantNon RoHSCompliantHCPL-2201 HCPL-2202 HCPL-2211 HCPL-2212-000E No option300milDIP-850 per tube -300E-300 X X50 per tube -500E-500X X X1000 per reel -060E-060X50 per tube -360E-360X X X50 per tube -560E-560X X X X1000 per reelHCPL-2231 HCPL-2232-000E No option50 per tube -300E-300 X X50 per tube -500E-500X X X1000 per reelHCPL-0201 HCPL-0211-000E No optionSO-8100 per tube -500E-500X X X1500 per reel -060E-060X100 per tube -560E-560X X X X1500 per reelHCNW2201 HCNW2211-000E No option400milWidebodyDIP-842 per tube -300E-300 X X42 per tube -500E-500X X X750 per reelTo order, choose a part number from the part number column and combine with the desired option from the option column to form an order entry.Example 1:HCPL-2202-560E to order product of 300mil DIP Gull Wing Surface Mount package in Tape and Reel packaging with IEC/EN/DIN EN 60747-5-2 Safety Approval in RoHS compliant.Example 2:HCPL-2202 to order product of 300mil DIP package in tube packaging and non RoHS compliant.Option datasheets are available. Contact your Avago sales representative or authorized distributor for information. Remarks: The notation ‘#XXX’ is used for existing products, while (new) products launched since 15th July 2001 and RoHS compliant option will use ‘-XXXE‘.Package Outline Drawings8-Pin DIP Package (HCPL-2201/02/11/12/31/32)8-Pin DIP Package with Gull Wing Surface Mount Option 300 (HCPL-2201/02/11/12/31/32)+ 0.076- 0.051(0.010+ 0.003)- 0.002)DIMENSIONS IN MILLIMETERS AND (INCHES).UR * MARKING CODE LETTER FOR OPTION NUMBERS "V" = OPTION 060OPTION NUMBERS 300 AND 500 NOT MARKED.NOTE: FLOATING LEAD PROTRUSION IS 0.25 mm (10 mils) MAX.1.080 ± 0.320(0.100)BSCDIMENSIONS IN MILLIMETERS (INCHES).LEAD COPLANARITY = 0.10 mm (0.004 INCHES).NOTE: FLOATING LEAD PROTRUSION IS 0.25 mm (10 mils) MAX.+ 0.076- 0.051+ 0.003)- 0.002)Small-Outline SO-8 Package (HCPL-0201/11)8-Pin Widebody DIP Package (HCNW2201/11)(0.012)MIN.5.207 ± 0.254 (0.205 ± 0.010)DIMENSIONS IN MILLIMETERS (INCHES).LEAD COPLANARITY = 0.10 mm (0.004 INCHES) MAX.NOTE: FLOATING LEAD PROTRUSION IS 0.15 mm (6 mils) MAX.*1.78 ± 0.15(0.070 ± 0.006)TYP.NOTE: FLOATING LEAD PROTRUSION IS 0.25 mm (10 mils) MAX.+ 0.076- 0.0051+ 0.003)- 0.002)8-Pin Widebody DIP Package with Gull Wing Surface Mount Option 300 (HCNW2201/11)Solder Reflow Temperature Profile1.78 ± 0.15(0.070 ± 0.006)MAX.BSCDIMENSIONS IN MILLIMETERS (INCHES).LEAD COPLANARITY = 0.10 mm (0.004 INCHES).NOTE: FLOATING LEAD PROTRUSION IS 0.25 mm (10 mils) MAX.TIME (SECONDS)T E M P E R A T U R E (°C )ROOM TEMPERATURENOTE:NON-HALIDE FLUX SHOULD BE USED.Regulatory InformationThe HCPL-22XX/02XX and HCNW22XX have been approved by the following organizations:ULRecognized under UL 1577, Component Recognition Program, File E55361.CSAApproved under CSA Component Acceptance Notice #5, File CA 88324.IEC/EN/DIN EN 60747-5-2Approved under:IEC 60747-5-2:1997 + A1:2002 EN 60747-5-2:2001 + A1:2002DIN EN 60747-5-2 (VDE 0884 Teil 2):2003-01(Option 060 and HCNW only)Recommended Pb-Free IR ProfileInsulation and Safety Related Specifications 8-pin DIP Package 8-Pin DIP Widebody (300 Mil) SO-8 (400 Mil) Parameter Symbol ValueValueValueUnitsConditionsMinimum External L(101) 7.1 4.9 9.6 mm Measured from input terminals Air Gap (External to output terminals, shortest Clearance) distance through air.Minimum External L(102) 7.4 4.8 10.0 mm Measured from input terminals Tracking (External to output terminals, shortest Creepage) distance path along body. Minimum Internal 0.08 0.08 1.0 mm Through insulation distance, Plastic Gapconductor to conductor, usually (Internal Clearance) the direct distance between the photoemitter and photodetectorinside the optocoupler cavity. Minimum Internal NA NA 4.0 mm Measured from input terminals Tracking (Internal to output terminals, along Creepage) internal cavity.Tracking Resistance CTI200200200VoltsDIN IEC 112/VDE 0303 Part 1(Comparative Tracking Index) Isolation Group IIIa IIIa IIIa Material Group(DIN VDE 0110, 1/89, Table 1)Option 300 - surface mount classification is Class A in accordance with CECC 00802.T LT smax T smin25T p TIMET E M P E R A T U R ENOTES:THE TIME FROM 25°C to PEAK TEMPERATURE =8MINUTES MAX.T smax =200°C,T smin =150°CNOTE:NON-HALIDE FLUX SHOULD BE USED.*RECOMMENDED PEAK TEMPERATUREFOR WIDEBODY 400mils PACKAGE IS 245°C(HCPL-2211/2212 Option 060 ONLY) DescriptionSymbolCharacteristicUnitsInstallation classification per DIN VDE 0110/1.89, Table 1 Climatic Classification55/85/21Pollution Degree (DIN VDE 0110/1.89) 2 Maximum Working Insulation VoltageV IORM 630 V peak Input to Output Test Voltage, Method b*V IORM x 1.875 = V PR , 100% Production Test with t m = 1 sec, V PR1181V peakPartial Discharge < 5 pCInput to Output Test Voltage, Method a* V IORM x 1.5 = V PR , Type and sample test, V PR945V peakt m = 60 sec, Partial Discharge < 5 pC Highest Allowable Overvoltage* (Transient Overvoltage, t ini = 10 sec) V IOTM6000V peakSafety Limiting Values(Maximum values allowed in the event of a failure, also see Figure 12, Thermal Derating curve.) Case Temperature T S175 °C Input Current I S,OUTPUT 230 mAOutput PowerP S,OUTPUT 600 mW Insulation Resistance at T S , V IO = 500 VR S≥109Ω*Refer to the front of the optocoupler section of the current catalog, under Product Safety Regulations section IEC/EN/DIN EN 60747-5-2, for a detailed description.Note: Isolation characteristics are guaranteed only within the safety maximum ratings which must be ensured by protective circuits in applica-tion.(HCNW22XX ONLY) DescriptionSymbolCharacteristicUnitsfor rated mains voltage ≤600 V rms I-IV Climatic Classification55/100/21Pollution Degree (DIN VDE 0110/1.89) 2 Maximum Working Insulation VoltageV IORM 1414 V peak Input to Output Test Voltage, Method b*V IORM x 1.875 = V PR , 100% Production Test with t m = 1 sec, V PR2652V peakPartial Discharge < 5 pCInput to Output Test Voltage, Method a* V IORM x 1.5 = V PR , Type and sample test, V PR2121V peakt m = 60 sec, Partial Discharge < 5 pC Highest Allowable Overvoltage* (Transient Overvoltage, t ini = 10 sec) V IOTM8000V peakSafety Limiting Values(Maximum values allowed in the event of a failure, also see Figure 12, Thermal Derating curve.) Case TemperatureT S150 °C Current (Input Current I F , P S = 0) I S,INPUT 400 mAOutput PowerP S,OUTPUT 700 mW Insulation Resistance at T S , V IO = 500 VR S≥109Ω*Refer to the front of the optocoupler section of the current catalog, under Product Safety Regulations section IEC/EN/DIN EN 60747-5-2, for a detailed description.Note: Isolation characteristics are guaranteed only within the safety maximum ratings which must be ensured by protective circuits in applica-tion.Absolute Maximum RatingsParameter Symbol Min. Max. Units Note-55 125 °CStorage Temperature TS-40 85 °C Operating Temperature TA10 mA 1 Average Forward Input Current IF(AVG)Peak Transient Input Current< 1% Duty Cycle)25 mA 1 Average Output Current IOSupply Voltage V0 20 VCCOutput Voltage V-0.5 20 V 1OOutput Power Dissipation PSee Figure 7 1OLead Solder Temperature (Through Hole Parts Only) 260°C for 10 sec.,Solder Reflow Temperature Profile See Package Outline Drawings section(Surface Mount Parts Only)Recommended Operating ConditionsParameter Symbol Min. Max. Units Power Supply Voltage V4.5 20 VCCForward Input Voltage (OFF) V- 0.8 VF(OFF)-40 85 °C Operating Temperature TAJunction Temperature T-40 125 °CJFan Out N 4 TTL Loads*The initial switching threshold is 1.6 mA or less. It is recommended that 2.2 mA be used to permit at least a 20% LED degradation guardband.†The initial switching threshold is 1.8 mA or less. It is recommended that 2.5 mA be used to permit at least a 20% LED degradation guardband.Electrical Specifications-40°C ≤ T A ≤ 85°C, 4.5 V ≤ V CC ≤ 20 V, 1.6 mA ≤ I F(ON)* ≤ 5 mA, 0 V ≤ V F(OFF) ≤ 0.8 V, unless otherwise specified.All Typicals at T A = 25°C. See Note 7. ParameterSym.Min.Typ.Max.UnitsTest Conditions F ig.NoteLogic Low Output Voltage V OL 0.5 V I OL = 6.4 mA (4 TTL Loads) 1, 3 1Input Reverse Breakdown BV 5 V I = 10 µA 1*For HCPL-223X, 1.8 mA ≤ I F(ON) ≤ 5 mA.**Typical V OH = V CC - 2.1 V.ParameterSym.DeviceMin.UnitsTest Conditions Fig.NoteLogic High|CM H | HCPL-2201/02 1,000 V/µs |V CM | = 50 V V CC = 5 V 101, 7Common Mode HCPL-0201I F = 1.6 mA †T A = 25°CTransient HCPL-2231CM HCNW2211 I F = 5.0 mA Logic Low|CM L | HCPL-2201/02 1,000 V/µs |V CM | = 50 V V F = 0 V 101, 7Common Mode HCPL-0201 V CC = 5 V Transient HCPL-2231T = 25°CHCPL-2232HCNW2211*For HCPL-223X, 1.8 mA ≤ I F(ON) ≤ 5 mA.†I F = 1.8 mA for HCPL-2231.‡I F = 1.8 mA for HCPL-2232.Switching Specifications (AC)-40°C ≤ T A ≤ 85°C, 4.5 V ≤ V CC ≤ 20 V, 1.6 mA ≤ I F(ON)* ≤ 5 mA, 0 V ≤ V F(OFF) ≤ 0.8 V.All Typicals at T A = 25°C, V CC = 5 V, I F(ON) = 3 mA unless otherwise specified. ParameterSym.Min.Typ.Max.UnitsTest ConditionsFig.NotePropagation Delay Time t 110 ns Without Peaking Capacitor 5, 6 1, 6Output Rise Time (10-90%) t r 30 ns 5, 9 1 Output Fall Time (90-10%)t f7ns5, 91Notes:1. Each channel.2. Derate total package power dissipation, P T , linearly above 70°C free-air temperature at a rate of 4.5 mW/°C.3. Duration of output short circuit time should not exceed 10 ms.4. For single devices, input capacitance is measured between pin 2 and pin 3.5. Device considered a two-terminal device: pins 1, 2, 3, and 4 shorted together and pins 5, 6, 7, and 8 shorted together.6. The t PLH propagation delay is measured from the 50% point on the leading edge of the input pulse to the 1.3 V point on the leading edge ofthe output pulse. The t PHL propagation delay is measured from the 50% point on the trailing edge of the input pulse to the 1.3 V point on the trailing edge of the output pulse.7. CM H is the maximum slew rate of the common mode voltage that can be sustained with the output voltage in the logic high state, V O > 2.0 V.CM L is the maximum slew rate of the common mode voltage that can be sustained with the output voltage in the logic low state, V O < 0.8 V. 8. For HCPL-2202/12, V O is on pin 6.9. Use of a 0.1 µF bypass capacitor connected between pins 5 and 8 is recommended.10. In accordance with UL 1577, each optocoupler is proof tested by applying an insulation test voltage ≥4500 V rms for one second (leakagedetection current limit, I I-O ≤5 µA). This test is performed before the 100% production test for partial discharge (Method b) shown in the IEC/EN/DIN EN 60747-5-2 Insulation Characteristics Table, if applicable.11. In accordance with UL 1577, each optocoupler is proof tested by applying an insulation test voltage ≥6000 V rms for one second (leakagedetection current limit, I I-O ≤5 µA). This test is performed before the 100% production test for partial discharge (Method b) shown in the IEC/EN/DIN EN 60747-5-2 Insulation Characteristics Table.12. For HCPL-2231/32 only. Measured between pins 1 and 2, shorted together, and pins 3 and 4, shorted together.Package Characteristics ParameterSym.Min.Typ.Max.UnitsTest ConditionsFig.Note12A Input-Input Insulation I I-I0.005 µA Relative Humidity = 45%, 12 Leakage Current t = 5 s, V I-I = 500 V Resistance (Input-Input) R I-I 1011 Ω V I-I = 500 V 12 Capacitance (Input-Input)C I-I0.25pFf = 1 MHz12*The Input-Output Momentary Withstand Voltage is a dielectric voltage rating that should not be interpreted as an input-output continuousvoltage rating. For the continuous voltage rating refer to the IEC/EN/DIN EN 60747-5-2 Insulation Characteristics Table (if applicable), your equip-ment level safety specification or Avago Application Note 1074 entitled “Optocoupler Input-Output Endurance Voltage,” publication number 5963-2203I O H – H I G H L E V E L O U T P U T C U R R E N T – m A-8T A – TEMPERATURE – °C HCPL-2201 fig 2-5-3-1-6-7-4-2V O – O U T P U T V O L T A G E– VI F – INPUT CURRENT – mAHCPL-2201 fig 3Figure 1. Typical logic low output voltage vs. tem-perature.Figure 2. Typical logic high output current vs. tem-perature.Figure 3. Typical output voltage vs. forward input current.I F – F O R W A R D C U R R E N T – m A0.001V F – FORWARD VOLTAGE – V 1.0HCPL-2201 fig 4a10000.010.110100HCPL-22XX I F – F O R W A R D C U R R E NT – m A0.001V F – FORWARD VOLTAGE – V1.0HCPL-2201 fig 4b10000.010.110100Figure 4. Typical input diode forward characteristic.Figure 5. Circuit for t PLH , t PHL , t r , t f .HCPL-2201 fig 5aΩARE INCLUDED IN C 1 AND C 2.D 2D 3D 4R 1I F (ON)2.15 k Ω1.6 mA 1.10 k Ω3 mA681 Ω5 mA ALL DIODES ARE 1N916 OR 1N3064.HCPL-2201 fig 5bΩARE INCLUDED IN C 1 AND C 2.D 2D 3D 4R 1I F (ON)1.96 k Ω1.8 mA 1.10 k Ω3 mA681 Ω5 mA ALL DIODES ARE 1N916 OR 1N3064.F (ON)OL* 0.1 µF BYPASS — SEE NOTE 9.V O L – L O W L E V E L O U T P U T V O L T A G E – VT A – TEMPERATURE – °CHCPL-2201 fig 11.00.40.60.80.20.10.30.50.70.9t P – P R O P A G A T I O N D E L A Y – n s50T A – TEMPERATURE – °C 200HCPL-2201 fig 6b250100150Figure 6. Typical propagation delays vs. temperature.Figure 7. Maximum output power per channel vs. sup-ply voltage.V O H – H I G H L E V E LO U T P U T V O L T A G E – VV CC – SUPPLY VOLTAGE – V 15HCPL-2201 fig 820510t r , t f – R I S E , F A L LT I M E – n sT A – TEMPERATURE – °CHCPL-2201 fig 910040608020Figure 8. Typical logic high output voltage vs. supply voltage.Figure 9. Typical rise, fall time vs. temperature.Figure 10. Test circuit for common mode transient immunity and typical waveforms.V CM (PEAK)OUTPUT V O * SEE NOTE 7, 9.** I F = 1.8 mA FOR HCPL-2231/32 DEVICES.0 V V OH|V CM |V OLV O (MAX.)*V O (MIN.)*SWITCH AT A: I F = 1.6 mA**SWITCH AT B: V F = 0 V CM(PEAK)OUTPUT V O * SEE NOTE 7, 9.** I F = 1.8 mA FOR HCPL-2231/32 DEVICES.0 VV OH|V CM |V OL V O (MAX.)*V O (MIN.)*SWITCH AT A: I F = 1.6 mA**F = 0 V t P – P R O P AG A T I O N D E L A Y – n sT A – TEMPERATURE – °C HCPL-2201 fig 6aHCPL-22XX P O – M A X I M U M O U T P U T P O W E R P E R C H A N N E L (m W )V CC – SUPPLY VOLTAGE – V60HCPL-2201 fig 7802040HCPL-2201/11HCPL-02XX HCPL-2201 fig 10aO R V FFHCPL-2201 fig 10bO V FFO U T P U T P O W E R – P S , I N P U T C U R R E N T – I S0T S – CASE TEMPERATURE – °C 400600800200100300500700Figure 11. Typical input threshold current vs. temperature.Figure 12. Thermal derating curve, dependence of safety limiting value with case temperature per IEC/EN/DIN EN 60747-5-2.Figure 13a. Recommended LSTTL to LSTTL circuit where 500 ns propagation delay is sufficient.HCPL-2201 fig 13aHCPL-2201/11HCPL-02XX DATA INPUTV CC2 (+5 V)UP TO 16 LSTTL LOADS OR 4 TTL LOADSV CC1DATA OUTPUTI N P U T C U R R E N T T H R E S H O L D – m A0.5T A – TEMPERATURE – °C HCPL-2201 fig 11a1.00.70.80.90.6HCPL-22XXI N P U T C U R R E N T T H R E S H O L D – m AT A – TEMPERATURE – °CHCPL-2201 fig 11bHCNW22XX O U T P U T P O W E R P S , I N P U T C U R R E N T I ST S – CASE TEMPERATURE – °CHCPL-2201 fig 12bFigure 16. Series LED drive with open collector gate (4.7 k resistor shunts I OH from the LED).Figure 14. LSTTL to CMOS interface circuit.HCPL-2201 fig 15HCPL-2201/11HCPL-02XX V CC1Figure 15. Alternative LED drive circuit.HCPL-2201/11HCPL-02XX V CC RESISTOR MAY BE SHORTED WHERE 500 ns PROPAGATION DELAY IS SUFFICIENT.Figure 13b. Recommended LSTTL to LSTTL circuit for applications requiring a maximum allowable propagation delay of 300 ns.HCPL-2201 fig 13bHCPL-2201/11HCPL-02XX DATA INPUTV CC2 (+5 V)UP TO 16 LSTTL LOADS OR 4 TTL LOADSV CC1 DATA OUTPUTHCPL-2201 fig 14V CC2 **0.1 µF BYPASSV CC1 DATA OUTPUTΩRESISTOR MAY BE SHORTED WHERE 500 ns PROPAGATION DELAY IS SUFFICIENT.10 V 15 V 20 V 2.37 k Ω3.83 k Ω5.11 k ΩFor product information and a complete list of distributors, please go to our website: Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies Limited in the United States and other countries. Data subject to change. Copyright © 2005-2008 Avago Technologies Limited. All rights reserved. Obsoletes AV01-0556ENAV02-0674EN - June 20, 2008。

1-120Low Input Current Logic Gate Optocouplers Technical DataHCPL-2200HCPL-2219CAUTION: It is advised that normal static precautions be taken in handling and assembly of this component to prevent damage and/or degradation which may be induced by ESD.Features• 2.5 kV/µs Minimum Common Mode Rejection (CMR) at V CM = 400 V (HCPL-2219)• Compatible with LSTTL,TTL, and CMOS Logic• Wide V CC Range (4.5 to 20V)• 2.5 Mbd Guaranteed over Temperature• Low Input Current (1.6 mA)• Three State Output (No Pullup Resistor Required)• Guaranteed Performance from 0°C to 85°C • Hysteresis• Safety ApprovalUL Recognized -2500 V rms for 1 minute CSA ApprovedVDE 0884 Approved with V IORM = 630 V peak(HCPL-2219 Option 060Only)• MIL-STD-1772 Version Available (HCPL-5200/1)Applications• Isolation of High SpeedLogic Systems• Computer-Peripheral Interfaces• Microprocessor System InterfacesFunctional Diagram• Ground Loop Elimination • Pulse Transformer Replacement• Isolated Buss Driver• High Speed Line ReceiverDescriptionThe HCPL-2200/2219 areoptically coupled logic gates that combine a GaAsP LED and an integrated high gain photodetector. The detector has a three state output stage and has adetector threshold with hysteresis.The three state output eliminates the need for a pullup resistor and allows for direct drive of data busses. The hysteresis provides differential mode noise immunity and eliminates the potential for output signal chatter.A superior internal shield on the HCPL-2219 guarantees common mode transient immunity of 2.5kV/µs at a common mode voltage of 400 volts.A 0.1 µF bypass capacitor must be connected between pins 5 and 8.NC ANODE CATHODE NC GNDV CC V O TRUTH TABLE (POSITIVE LOGIC)LED ON OFF ON OFF ENABLE H H L LV E OUTPUT Z Z H L 5965-3596EHV FV CCV OGNDV EThe Electrical and SwitchingCharacteristics of the HCPL-2200/2219 are guaranteed overthe temperature range of 0°C to85°C and a V CC range of 4.5 voltsto 20 volts. Low I F and wide V CCrange allow compatibility withTTL, LSTTL, and CMOS logic andresult in lower power consump-tion compared to other highspeed optocouplers. Logic signalsare transmitted with a typicalpropagation delay of 160 nsec.Selection GuideNotes:1. HCPL-2200/2219 devices include output enable/disable functionality.2. Minimum CMR of 10 kV/µs with V CM = 1000 V can be achieved with input current, I F, of 5 mA.Ordering InformationSpecify Part Number followed by Option Number (if desired).Example:HCPL-2219#XXX060 = VDE 0884 V IORM = 630 Vpeak Option*300 = Gull Wing Surface Mount Option500 = Tape and Reel Packaging OptionOption data sheets available. Contact your Hewlett-Packard sales representative or authorized distributor for information.*For HCPL-2219 only.SchematicThe HCPL-2200/2219 are usefulfor isolating high speed logicinterfaces, buffering of input andoutput lines, and implementingisolated line receivers in highnoise environments.1-121DIMENSIONS IN MILLIMETERS AND (INCHES).*MARKING CODE LETTER FOR OPTION NUMBERS."V" = OPTION 060OPTION NUMBERS 300 AND 500 NOT MARKED.0.254+ 0.076- 0.051(0.010+ 0.003)- 0.002)Package Outline Drawings8-Pin DIP Package8-Pin DIP Package with Gull Wing Surface Mount Option 300(0.025 ± 0.005)1.080 ± 0.320MAX.(0.100)BSCDIMENSIONS IN MILLIMETERS (INCHES).LEAD COPLANARITY = 0.10 mm (0.004 INCHES).+ 0.076- 0.051+ 0.003)- 0.002)1-1221-123Note: Use of nonchlorine activated fluxes is highly recommended.Maximum Solder Reflow Thermal Profile240TIME – MINUTEST E M P E R A T U R E – °C220200180160140120100806040200260Regulatory InformationThe HCPL-2200/2219 have been approved by the following organizations:ULRecognized under UL 1577,Component Recognition Program, File E55361.CSAApproved under CSA Component Acceptance Notice #5, File CA 88324.VDEApproved according to VDE0884/06.92. (HCPL-2219 Option 060 Only)Insulation and Safety Related SpecificationsParameter Symbol Value Units Conditions Min. External Air Gap L(IO1)7.1mm Measured from input terminals to output terminals,(External Clearance)shortest distance through air.Min. External L(IO2)7.4mm Measured from input terminals to output terminals,Tracking Path shortest distance path along body .(External Creepage)Minimum Internal 0.08mm Through insulation distance, conductor to conductor,Plastic Gap usually the direct distance between the photoemitter (Internal Clearance)and photodetector inside the optocoupler cavity .Tracking Resistance CTI 200V DIN IEC 112/VDE 0303 Part 1(Comparative Tracking Index)Isolation Group IIIa Material Group (DIN VDE 0110, 1/89, Table 1)Option 300 - surface mount classification is Class A in accordance with CECC 00802.VDE 0884 Insulation Related Characteristics (HCPL-2219 OPTION 060 ONLY)*Refer to the front of the optocoupler section of the current catalog, under Product Safety Regulations section, (VDE 0884), for a detailed description.Note: Isolation characteristics are guaranteed only within the safety maximum ratings which must be ensured by protective circuits in application.1-124Absolute Maximum Ratings(No Derating Required up to 70°C)Parameter Symbol Min.Max.Units Note Storage Temperature T S-55125°COperating Temperature T A-4085°C1 Average Forward Input Current I F(AVG)10mAPeak Transient Input Current I F(TRAN) 1.0A(≤1 µs Pulse Width, 300 pps)Reverse Input Voltage V R5VAverage Output Current I O25mASupply Voltage V CC020VThree State Enable Voltage V E-0.520VOutput Voltage V O-0.520VTotal Package Power Dissipation P T210mW1 Lead Solder Temperature260°C for 10 sec., 1.6 mm below seating planeSolder Reflow Temperature Profile See Package Outline Drawings sectionRecommended Operating ConditionsParameter Symbol Min.Max.UnitsPower Supply Voltage V CC 4.520VEnable Voltage High V EH 2.020VEnable Voltage Low V EL00.8VForward Input Current I F(ON) 1.6*5mAForward Input Current I F(OFF)–0.1mAOperating Temperature T A085[1]°CFan Out N4TTL Loads*The initial switching threshold is 1.6 mA or less. It is recommended that 2.2 mA beused to permit at least a 20% CTR degradation guardband.1-125Electrical SpecificationsFor 0°C ≤T A[1]≤85°C, 4.5 V ≤V CC≤20 V, 1.6 mA ≤I F(ON)≤5 mA, 2.0 V ≤V EH≤20 V,0.0 V ≤V EL≤ 0.8 V, 0 mA ≤I F(OFF)≤0.1 mA. All Typicals at T A = 25°C, V CC = 5 V, I F(ON) = 3 mA unless otherwise specified. See Note 7.1-1261-127Switching Specifications (AC)For 0°C ≤T A [1] ≤ 85°C, 4.5 V ≤V CC ≤20 V, 1.6 mA ≤I F(ON) ≤5 mA, 0.0 mA ≤I F(OFF) ≤0.1 mA.All Typicals at T A = 25°C, V CC = 5 V, I F(ON) = 3 mA unless otherwise specified.Parameter Sym.Device Min.UnitsTest ConditionsFig.Note Logic High |CM H |I F = 1.6 mA116Common Mode V CC = 5 V Transient T A = 25°CImmunity Logic Low|CM L |V F = 0 V 116Common Mode V CC = 5 V Transient T A = 25°CImmunityHCPL-22001,000 V/µs |V CM | = 50 VHCPL-22192,500 V/µs |V CM | = 400 V HCPL-22001,000 V/µs |V CM | = 50 V HCPL-22192,500 V/µs|V CM | = 400 VPackage CharacteristicsParameterSym.Min.Typ.Max.UnitsTest Conditions Fig.NoteInput-Output Momentary V ISO 2500V rmsRH ≤50%, t = 1 min.,3, 8Withstand Voltage*T A = 25°CInput-Output Resistance R I-O 1012ΩV I-O = 500 VDC3Input-Output CapacitanceC I-O0.6pFf = 1 MHz, V I-O = 0 VDC3*The Input-Output Momentary Withstand Voltage is a dielectric voltage rating that should not be interpreted as an input-output continuous voltage rating. For the continuous voltage rating refer to the VDE 0884 Insulation Characteristics Table (if applicable), your equipment level safety specification or HP Application Note 1074 entitled “Optocoupler Input-Output Endurance Voltage,” publication number 5963-2203E.1-128OLINPUT I V OFigure 2. Typical Logic High Output Current vs. Temperature.Figure 3. Output Voltage vs. Forward Input Current.Figure 4. Typical Input Diode Forward Characteristic.Figure 1. Typical Logic Low Output Voltage vs. Temperature.Notes:1. Derate total package power dissipa-tion, P T , linearly above 70°C free air temperature at a rate of 4.5mW/°C.2. Duration of output short circuit time should not exceed 10 ms.3. Device considered a two-terminal device: pins 1, 2, 3, and 4 shorted together and pins 5, 6, 7, and 8shorted together.4. The t PLH propagation delay ismeasured from the 50% point on the leading edge of the input pulse to the 1.3 V point on the leading edge of the output pulse. The t PHL propagation delay is measured from the 50% point on the trailing edge of the input pulse to the 1.3 V point on the trailing edge of the output pulse.5. When the peaking capacitor is omitted,propagation delay times may increase by 100 ns.6. CM L is the maximum rate of rise of the common mode voltage that can besustained with the output voltage in the logic low state (V O < 0.8 V). CM H is the maximum rate of fall of the common mode voltage that can beI O H – H I G H L E V E L O U T P U T C U R R E N T – m AT A – TEMPERATURE – °C I F – F O R W A R D C U R R E N T – m A0.001V F – FORWARD VOLTAGE – V1.010000.010.110100sustained with the output voltage in the logic high state (V O > 2.0 V).7. Use of a 0.1 µF bypass capacitor connected between pins 5 and 8 is recommended.8. In accordance with UL1577, eachoptocoupler is proof tested by applying an insulation test voltage ≥3000 V rms for one second (leakage detection current limit, I I-O ≤5 µA). This test is performed before the 100% production test for partial discharge (Method b)shown in the VDE 0884 Insulation Characteristics Table, if applicable.Figure 5. Test Circuit for t PLH , t PHL , t r , and t f .V O L – L O W L E V E L O U T P U T V O L T A G E – VT A – TEMPERATURE – °CV O – O U T P U T V O L T A G E – VI F – INPUT CURRENT – mAΩARE INCLUDED IN C 1 AND C 2.D 2D 3D 4R II F (ON)2.15 k Ω1.6 mA 1.10 k Ω3 mA681 Ω5 mA ALL DIODES ARE 1N916 OR 1N3064.1-129INPUT V EOUTPUT V O 1.5 VOUTPUT V OΩNODED 2D 3D 4Figure 10. Typical Rise, Fall Time vs.Temperature.Figure 8. Typical Logic Low Enable Propagation Delay vs. Temperature.Figure 9. Typical Logic High Enable Propagation Delay vs. Temperature.Figure 7. Test Circuit for t PHZ , t PZH , t PLZ , and t PZL .Figure 6. Typical Propagation Delays vs. Temperature.T p – E N A B L E P RO P A G A T I O N D E L A Y – n sT A – TEMPERATURE – °C t P – E N A B L EP R O P A G A T I O N D E L A Y – n sT A – TEMPERATURE – °C 15020050100t P – P R O P A G A T I O N D E L A Y – n s50T A – TEMPERATURE – °C200250100150t r , t f – R I S E , F A L L T I M E – n sT A – TEMPERATURE – °C120408010020601-130V CC150 VOUTPUT V O* SEE NOTE 6.0 V V OHV OLV O (MAX.)*V O (MIN.)*SWITCH AT A: I F = 1.6 mA SWITCH AT B: I F = 0 mAV CMFigure 11. Test Circuit for Common Mode Transient Immunity and Typical Waveforms.Figure 13. Recommended LSTTL to LSTTL Circuit.Figure 15. Recommended LED Drive Circuit.Figure 12. Thermal Derating Curve,Dependence of Safety Limiting Value with Case Temperature per VDE 0884.Figure 14. LSTTL to CMOS Interface Circuit.Figure 16. Series LED Drive with Open Collector Gate (4.7 k Ω Resistor Shunts I OH from the LED).*The 120 pF capacitor may be omitted in applications where 500 ns propagation delay is sufficient.O RV FFO U T P U T P O W E R – P S , I N P U T C U R R E N T – I S0T S – CASE TEMPERATURE – °C400600800200100300500700DATA INPUT V CC2(+5 V)V DATAOUTPUTV CCDATA INPUT V DATA OUTPUT15 V 20 V3.83 K 5.11 K元器件交易网。

Single-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor OptocouplersSingle-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor OptocouplersSingle-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor OptocouplersSingle-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor OptocouplersSingle-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor Optocouplers Switching Characteristics(T A = 0 to 70°C unless otherwise specified., V CC = 5V)** All T ypicals at T A = 25°C Notes:6. The 4.1kΩ load represents 1 LSTTL unit load of 0.36mA and 6.1kΩ pull-up resistor.7.The 1.9kΩ load represents 1 TTL unit load of 1.6mA and 5.6kΩ pull-up mon mode transient immunity in logic high level is the maximum tolerable (positive) dV cm/dt on the leading edge of the common mode pulse signal V CM, to assure that the output will remain in a logic high state (i.e., V O > 2.0V).Common mode transient immunity in logic low level is the maximum tolerable (negative) dV cm/dt on the trailing edge of the common mode pulse signal, V CM, to assure that the output will remain in a logic low state (i.e., V O < 0.8V).Symbol Parameter Test Conditions Device Min.Typ.*Max.Unit T PHL Propagation Delay Time to Logic LOW T A = 25°C, R L = 4.1kΩ, I F = 16mA(6) (Fig. 7)6N135HCPL-25300.45 1.5µs R L = 1.9kΩ, I F = 16mA, T A = 25°C(7) (Fig. 7)6N136HCPL-4502HCPL-2503HCPL-25310.450.8µs R L = 4.1kΩ, I F = 16mA(6) (Fig. 7)6N135HCPL-2530 2.0µs R L = 1.9kΩ, I F = 16mA(7) (Fig. 7)6N136HCPL-4502HCPL-2503HCPL-2531 1.0µs T PLH Propagation Delay Time to Logic HIGH T A = 25°C, (R L = 4.1kΩ, I F = 16mA(6) (Fig. 7) 6N135HCPL-25300.5 1.5µs R L = 1.9kΩ, I F = 16mA(7) (Fig. 7)T A = 25°C6N136HCPL-4502HCPL-2503HCPL-25310.30.8µs R L = 4.1kΩ, I F = 16mA(6) (Fig. 7)6N135HCPL-2530 2.0µs R L = 1.9kΩ, I F = 16mA(7) (Fig. 7)6N136HCPL-4502HCPL-2503HCPL-2531 1.0µs|CM H|Common Mode T ransient Immunity at Logic High I F = 0mA, V CM = 10V P-P,, R L = 4.1kΩ, T A = 25°C(8) (Fig. 8) 6N135HCPL-253010,000V/µs I F = 0mA, V CM = 10V P-P,R L = 1.9kΩ, T A = 25°C(8) (Fig. 8)6N136HCPL-4502HCPL-2503HCPL-253110,000V/µs|CM L|Common Mode T ransient Immunity at Logic Low I F = 16mA, V CM = 10 V P-P, R L = 4.1kΩ, T A = 25°C(8) (Fig. 8) 6N135HCPL-253010,000V/µs I F = 16mA, V CM = 10 V P-P, R L = 1.9kΩ(8) (Fig. 8)6N136HCPL-4502HCPL-2503HCPL-253110,000V/µsSingle-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor Optocouplers Isolation Characteristics(T A = 0 to 70°C Unless otherwise specified)Notes:9.Device is considered a two terminal device: Pins 1, 2, 3 and 4 are shorted together and Pins 5, 6, 7 and 8 are shorted together.10.Measured between pins 1 and 2 shorted together, and pins 3 and 4 shorted together.Symbol Characteristics Test Conditions Min Typ**Max Unit I I-O Input-Output Insulation Leakage Current Relative humidity = 45%,T A = 25°C, t = 5s, V I-O = 3000 VDC(9) 1.0µA V ISO Withstand Insulation T est Voltage RH ≤ 50%, T A = 25°C, I I-O≤ 2 µA, t = 1 min.(9)2500V RMS R I-O Resistance (Input to Output)V I-O = 500VDC(9)1012ΩC I-O Capacitance (Input to Output) f = 1 MHz(9)0.6pF HFE DC Current Gain I O = 3mA, V O = 5V(9)150I I-I Input-Input Insulation Leakage Current RH ≤ 45%, V I-I = 500VDC(10) t = 5 s, (HCPL-2530/2531 only)0.005µA R I-I Input-Input Resistance V I-I = 500 VDC(10) (HCPL-2530/2531 only)1011ΩC I-I Input-Input Capacitance f = 1MHz)(10) (HCPL-2530/2531 only)0.03pFSingle-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor OptocouplersSingle-Channel: 6N135, 6N136 , HCPL-2503, HCPL-4502 Dual-Channel: HCPL-2530, HCPL-2531 High Speed Transistor Optocouplers。

The HCPL-3020 in DIP-8 and HCPL-0302 in SO-8 package complement Agilent’s existing family of gate drive optocouplers. The new 0.2 A devices consist of GaAsP LEDs optically coupled toan integrated circuit witha power output stage. The current rating, combined with the high commonmode rejection (CMR),fast switching and latch-up performance uniquely qualify these optocouplers for low-power inverter gate drive applications. The high operating voltage ranges of the HCPL-3020 and HCPL-0302 output stages provide the drive voltages required by MOS-gated devices like IGBTs or MOSFETs. The voltage and current provided by these optocouplers make it suitable for driving IGBTs with rating up to 1200 V/20 A. For IGBTs with higher ratings, the HCPL-0314/3140 (0.4 A), HCPL-3150 (0.5 A) or HCPL-3120 (2 A) can be used. The HCPL-3020 and HCPL-0302 are among the cheapest solutions available for driving MOS-gated devices in a safe, effi cient, reliable and cost-effective way. Besides ease of implementation,the HCPL-3020 and HCPL-0302 also excel in power consumption. The low supply current of 3 mA allows bootstrap techniques, thuseliminating additionalisolated power supplies forgate drive circuitry. Usingdiscrete power IGBTs orMOSFETs together with gatedrive optoisolators insteadof integrated modulesallows the designer tocontrol the gate signal fl ow.This makes it possible tochange the switching speedand related EMI behavior.Compared with high-voltageintegrated circuits (HVICs)Agilent’s optocouplers offersuperior galvanic isolation.The optoisolators feature aproprietary internal Faradayshield, which provides thebest common-mode rejection(CMR) performance of anycompeting isolation solution.Features• 0.2 A min. peakoutput current• H igh-speed response:0.7 µs max. propagationdelay over temp. range• U ltra-high CMR: min.10 kV/µs @ VCM= 1000 V• B ootstrappable supplycurrent: max. 3 mA• W ide operating temp.range: -40…+100 °C• W ide VCCoperating range:10…30 V overtemp. range• D IP-8 and SO-8 packages• U L approval: 2500 VRMSfor 1 minute• C SA approval pending• V DE approval pending:• V IORM = 630 V PEAK(HCPL-3020)• V IORM = 566 V PEAK(HCPL-0302)Applications• I solated IGBT/powerMOSFET gate drive• A C and brushlessDC motor drives• I ndustrial inverters• A ir conditioners• W ashing machines• I nduction heatersfor cookers• S witching powersupplies (SPS)0.2 A Output Current Gate Drive Optocoupler from Agilent TechnologiesMichael Prangs, EBV Kaarst24MIP Edition 3/2003。

注册分类第1 页共126 页上海玉瑞生物科技（安阳）药业有限公司硝苯平缓释片（Ⅱ）申报生产资料 模块 --3.2.P.5 制剂质量控制CTD第 2 页 共 126页表 3.2.P.5.3.2-2 鉴别（二）保留时间统计表表 3.2.P.5.3.3.3.1-2 中国药典流动相（甲醇 - 水（ 60：40））实验结果注：峰纯度合格标准：纯度角度＜纯度阈值。

结论：中国药典流动相中酸破坏样品杂质Ⅰ峰、杂质Ⅱ峰纯度不合格，且杂质Ⅰ峰与前杂质峰分离度不合格。

碱破坏样品杂质Ⅰ峰纯度不合格表 3.2.P.5.3.3.3.1-3美国药典流动相（乙腈 - 甲醇 - 水（ 50：25：25））实验结果上海玉瑞生物科技（安阳）药业有限公司硝苯平缓释片（Ⅱ）申报生产资料CTD 模块--3.2.P.5 制剂质量控制注：峰纯度合格标准：纯度角度＜纯度阈值。

结论：美国药典流动相中光照破坏样品杂质Ⅰ峰纯度不合格，酸破坏样品杂质Ⅰ峰纯度不合格，且杂质Ⅰ峰与前杂质峰分离度不合格。

碱破坏样品杂质Ⅱ峰纯度不合格。

; 表3.2.P.5.3.3.3.1-4英国药典流动相（乙腈- 甲醇- 水（9：36：55））实验结果第3 页共126页上海玉瑞生物科技（安阳）药业有限公司硝苯平缓释片（Ⅱ）申报生产资料 模块 --3.2.P.5 制剂质量控制CTD第 4 页 共 126页注：峰纯度合格标准：纯度角度＜纯度阈值。

结论：各破坏样品溶液中，主峰、杂质Ⅰ、Ⅱ与前后峰分离度均符合规定，峰纯度均符合要求，但主峰保留时间达到 时间可能过长。

45分钟, 后续可能杂质洗脱上海玉瑞生物科技（安阳）药业有限公司硝苯平缓释片（Ⅱ）申报生产资料 模块 --3.2.P.5 制剂质量控制第 5 页 共 126 页CTD① 中国药典流动相改进 总流速 :1.0ml/min 流动相：甲醇 - 水（45：55）表 3.2.P.5.3.3.3.2-2中国药典流动相改进（甲醇：水 -45 ：55）注：峰纯度合格标准：纯度角度＜纯度阈值。

Low Input Current Logic Gate Optocouplers Technical DataHCPL-2200HCPL-2219CAUTION: It is advised that normal static precautions be taken in handling and assembly of this component to prevent damage and/or degradation which may be induced by ESD.Features• 2.5 kV/µs Minimum Common Mode Rejection (CMR) at V CM = 400 V (HCPL-2219)• Compatible with LSTTL,TTL, and CMOS Logic• Wide V CC Range (4.5 to 20V)• 2.5 Mbd Guaranteed over Temperature• Low Input Current (1.6 mA)• Three State Output (No Pullup Resistor Required)• Guaranteed Performance from 0°C to 85°C • Hysteresis• Safety ApprovalUL Recognized -2500 V rms for 1 minute CSA ApprovedVDE 0884 Approved with V IORM = 630 V peak(HCPL-2219 Option 060Only)• MIL-STD-1772 Version Available (HCPL-5200/1)Applications• Isolation of High SpeedLogic Systems• Computer-Peripheral Interfaces• Microprocessor System InterfacesFunctional Diagram• Ground Loop Elimination • Pulse Transformer Replacement• Isolated Buss Driver• High Speed Line ReceiverDescriptionThe HCPL-2200/2219 areoptically coupled logic gates that combine a GaAsP LED and an integrated high gain photodetector. The detector has a three state output stage and has adetector threshold with hysteresis.The three state output eliminates the need for a pullup resistor and allows for direct drive of data busses. The hysteresis provides differential mode noise immunity and eliminates the potential for output signal chatter.A superior internal shield on the HCPL-2219 guarantees common mode transient immunity of 2.5kV/µs at a common mode voltage of 400 volts.A 0.1 µF bypass capacitor must be connected between pins 5 and 8.71234568NC ANODE CATHODE NC GNDV CC V O SHIELDTRUTH TABLE (POSITIVE LOGIC)LED ON OFF ON OFF ENABLE H H L LV E OUTPUT Z Z H LV F V CCV O GNDV E The Electrical and Switching Characteristics of the HCPL-2200/2219 are guaranteed over the temperature range of 0°C to 85°C and a V CC range of 4.5 volts to 20 volts. Low I F and wide V CC range allow compatibility withTTL, LSTTL, and CMOS logic and result in lower power consump-tion compared to other highspeed optocouplers. Logic signals are transmitted with a typical propagation delay of 160 nsec.Selection GuideNotes:1. HCPL-2200/2219 devices include output enable/disable functionality.2. Minimum CMR of 10 kV/µs with V CM = 1000 V can be achieved with input current, I F , of 5 mA.Ordering InformationSpecify Part Number followed by Option Number (if desired).Example:HCPL-2219#XXX060 = VDE 0884 V IORM = 630 Vpeak Option*300 = Gull Wing Surface Mount Option 500 = Tape and Reel Packaging OptionOption data sheets available. Contact your Agilent sales representative or authorized distributor for information.*For HCPL-2219 only.SchematicThe HCPL-2200/2219 are useful for isolating high speed logic interfaces, buffering of input and output lines, and implementing isolated line receivers in high noise environments.Package Outline Drawings8-Pin DIP Package8-Pin DIP Package with Gull Wing Surface Mount Option 300(0.025 ± 0.005)1.080 ± 0.320 MAX.(0.100)BSCDIMENSIONS IN MILLIMETERS (INCHES).LEAD COPLANARITY = 0.10 mm (0.004 INCHES).+ 0.076 - 0.051+ 0.003) - 0.002)DIMENSIONS IN MILLIMETERS AND (INCHES).*MARKING CODE LETTER FOR OPTION NUMBERS. "V" = OPTION 060OPTION NUMBERS 300 AND 500 NOT MARKED.+ 0.076 - 0.051(0.010+ 0.003) - 0.002)Note: Use of nonchlorine activated fluxes is highly recommended.Maximum Solder Reflow Thermal Profile240TIME – MINUTEST E M P E R A T U R E – °C220200180160140120100806040200260Regulatory InformationThe HCPL-2200/2219 have been approved by the following organizations:ULRecognized under UL 1577,Component Recognition Program, File E55361.CSAApproved under CSA Component Acceptance Notice #5, File CA 88324.VDEApproved according to VDE0884/06.92. (HCPL-2219 Option 060 Only)Insulation and Safety Related SpecificationsParameter Symbol Value Units Conditions Min. External Air Gap L(IO1)7.1mm Measured from input terminals to output terminals,(External Clearance)shortest distance through air.Min. External L(IO2)7.4mm Measured from input terminals to output terminals,Tracking Path shortest distance path along body.(External Creepage)Minimum Internal 0.08mm Through insulation distance, conductor to conductor,Plastic Gap usually the direct distance between the photoemitter (Internal Clearance)and photodetector inside the optocoupler cavity .Tracking Resistance CTI 200V DIN IEC 112/VDE 0303 Part 1(Comparative Tracking Index)Isolation Group IIIa Material Group (DIN VDE 0110, 1/89, Table 1)Option 300 - surface mount classification is Class A in accordance with CECC 00802.VDE 0884 Insulation Related Characteristics (HCPL-2219 OPTION 060 ONLY)*Refer to the front of the optocoupler section of the current catalog, under Product Safety Regulations section, (VDE 0884), for a detailed description.Note: Isolation characteristics are guaranteed only within the safety maximum ratings which must be ensured by protective circuits in application.Absolute Maximum Ratings(No Derating Required up to 70°C)Parameter Symbol Min.Max.Units Note Storage Temperature T S-55125°COperating Temperature T A-4085°C1 Average Forward Input Current I F(AVG)10mAPeak Transient Input Current I F(TRAN) 1.0A(≤1 µs Pulse Width, 300 pps)Reverse Input Voltage V R5VAverage Output Current I O25mASupply Voltage V CC020VThree State Enable Voltage V E-0.520VOutput Voltage V O-0.520VTotal Package Power Dissipation P T210mW1 Lead Solder Temperature260°C for 10 sec., 1.6 mm below seating planeSolder Reflow Temperature Profile See Package Outline Drawings sectionRecommended Operating ConditionsParameter Symbol Min.Max.UnitsPower Supply Voltage V CC 4.520VEnable Voltage High V EH 2.020VEnable Voltage Low V EL00.8VForward Input Current I F(ON) 1.6*5mAForward Input Current I F(OFF)–0.1mAOperating Temperature T A085[1]°CFan Out N4TTL Loads*The initial switching threshold is 1.6 mA or less. It is recommended that 2.2 mA beused to permit at least a 20% CTR degradation guardband.Electrical SpecificationsFor 0°C ≤T A[1]≤85°C, 4.5 V ≤V CC≤20 V, 1.6 mA ≤I F(ON)≤5 mA, 2.0 V ≤V EH≤20 V,0.0 V ≤V EL≤ 0.8 V, 0 mA ≤I F(OFF)≤0.1 mA. All Typicals at T A = 25°C, V CC = 5 V, I F(ON) = 3 mA unless otherwise specified. See Note 7.Switching Specifications (AC)For 0°C ≤T A [1] ≤ 85°C, 4.5 V ≤V CC ≤20 V, 1.6 mA ≤I F(ON) ≤5 mA, 0.0 mA ≤I F(OFF) ≤0.1 mA.All Typicals at T A = 25°C, V CC = 5 V, I F(ON) = 3 mA unless otherwise specified.Parameter Sym.Device Min.UnitsTest ConditionsFig.Note Logic High |CM H |I F = 1.6 mA116Common Mode V CC = 5 V Transient T A = 25°CImmunity Logic Low|CM L |V F = 0 V 116Common Mode V CC = 5 V Transient T A = 25°CImmunityHCPL-22001,000 V/µs |V CM | = 50 VHCPL-22192,500 V/µs |V CM | = 400 V HCPL-22001,000 V/µs |V CM | = 50 V HCPL-22192,500V/µs|V CM | = 400 VPackage CharacteristicsParameterSym.Min.Typ.Max.UnitsTest Conditions Fig.NoteInput-Output Momentary V ISO 2500V rmsRH ≤50%, t = 1 min.,3, 8Withstand Voltage*T A = 25°CInput-Output Resistance R I-O 1012ΩV I-O = 500 VDC3Input-Output CapacitanceC I-O0.6pFf = 1 MHz, V I-O = 0 VDC3*The Input-Output Momentary Withstand Voltage is a dielectric voltage rating that should not be interpreted as an input-output continuous voltage rating. For the continuous voltage rating refer to the VDE 0884 Insulation Characteristics Table (if applicable), your equipment level safety specification or Agilent Application Note 1074 entitled “Optocoupler Input-Output Endurance Voltage,” publication number 5963-2203E.OLINPUT I V OFigure 2. Typical Logic High Output Current vs. Temperature.Figure 3. Output Voltage vs. Forward Input Current.Figure 4. Typical Input Diode Forward Characteristic.Figure 1. Typical Logic Low Output Voltage vs. Temperature.Notes:1. Derate total package power dissipa-tion, P T , linearly above 70°C free air temperature at a rate of 4.5mW/°C.2. Duration of output short circuit time should not exceed 10 ms.3. Device considered a two-terminal device: pins 1, 2, 3, and 4 shorted together and pins 5, 6, 7, and 8shorted together.4. The t PLH propagation delay ismeasured from the 50% point on the leading edge of the input pulse to the 1.3 V point on the leading edge of the output pulse. The t PHL propagation delay is measured from the 50% point on the trailing edge of the input pulse to the 1.3 V point on the trailing edge of the output pulse.5. When the peaking capacitor is omitted,propagation delay times may increase by 100 ns.6. CM L is the maximum rate of rise of the common mode voltage that can besustained with the output voltage in the logic low state (V O < 0.8 V). CM H is the maximum rate of fall of the common mode voltage that can beI O H – H I G H L E V E L O U T P U T C U R R E N T – m A-8T A – TEMPERATURE – °C 0-5-3-1-6-7-4-2I F – F O R W A R D C U R R E N T – m AV F – FORWARD VOLTAGE – Vsustained with the output voltage in the logic high state (V O > 2.0 V).7. Use of a 0.1 µF bypass capacitor connected between pins 5 and 8 is recommended.8. In accordance with UL1577, eachoptocoupler is proof tested by applying an insulation test voltage ≥3000 V rms for one second (leakage detection current limit, I I-O ≤5 µA). This test is performed before the 100% production test for partial discharge (Method b)shown in the VDE 0884 Insulation Characteristics Table, if applicable.Figure 5. Test Circuit for t PLH , t PHL , t r , and t f .V O L – L O W L E V E L O U T P U T V O L T A G E – VT A – TEMPERATURE – °CV O – O U T P U T V O L T A G E – V0I F – INPUT CURRENT – mA52314ΩARE INCLUDED IN C 1 AND C 2.D 2D 3D 4R II F (ON)2.15 k Ω1.6 mA 1.10 k Ω3 mA681 Ω5 mA ALL DIODES ARE 1N916 OR 1N3064.INPUT V EOUTPUT V O 1.5 VOUTPUT V OΩNODED 2D 3D 4Figure 10. Typical Rise, Fall Time vs.Temperature.Figure 8. Typical Logic Low Enable Propagation Delay vs. Temperature.Figure 9. Typical Logic High Enable Propagation Delay vs. Temperature.Figure 7. Test Circuit for t PHZ , t PZH , t PLZ , and t PZL .Figure 6. Typical Propagation Delays vs. Temperature.T p – E N A B L E P RO P A G A T I O N D E L A Y – n sT A – TEMPERATURE – °C t P – E N A B L EP R O P A G A T I O N D E L A Y – n sT A – TEMPERATURE – °C 15020050100t P – P R O P A G A T I O N D E L A Y – n s50T A – TEMPERATURE – °C200250100150t r , t f – R I S E , F A L L T I M E – n sT A – TEMPERATURE – °C1204080100206011V CC150 VOUTPUT V O* SEE NOTE 6.0 V V OHV OLV O (MAX.)*V O (MIN.)*SWITCH AT A: I F = 1.6 mA SWITCH AT B: I F = 0 mAV CMFigure 11. Test Circuit for Common Mode Transient Immunity and Typical Waveforms.Figure 13. Recommended LSTTL to LSTTL Circuit.Figure 15. Recommended LED Drive Circuit.Figure 12. Thermal Derating Curve,Dependence of Safety Limiting Value with Case Temperature per VDE 0884.Figure 14. LSTTL to CMOS Interface Circuit.Figure 16. Series LED Drive with Open Collector Gate (4.7 k Ω Resistor Shunts I OH from the LED).*The 120 pF capacitor may be omitted in applications where 500 ns propagation delay is sufficient.O RV FFO U T P U T P O W E R – P S , I N P U T C U R R E N T – I S0T S – CASE TEMPERATURE – °C400600800200100300500700DATA INPUT V CC2(+5 V)V DATAOUTPUTDATA INPUT V CCDATA INPUT V DATA OUTPUT15 V 20 V3.83 K 5.11 K Data subject to change.Copyright © 1999 Agilent Technologies Obsoletes 5962-6298E5965-3596E (11/99)。

摘要塑料注射成型机是一种能将塑料加热塑化，借助推进机构把熔化的塑料注入模具型腔内，经冷却、定型后形成制品的塑料成型加工设备。

它能配置不同的模具，可一次成型外形复杂的制品，是塑料机械中主要机种之一。

塑料注塑成型机有很多型式，液压式塑料成型机就是其中之一，其主要由合模机构，注射部件，液压传动及电气控制系统等几部分组成，而液压泵，液压缸、各种液压阀、电机、电气元件以及控制仪表是其中不可缺少的控制元件。

塑料注射成型机以其成型周期短，对各种塑料的加工适用性强，尺寸较精确以及自动化程度高等优点，得到了广泛应用。

关键词：塑料注射成型机、液压系统、液压泵、液压缸、液压阀ABSTRACTThe plastic casts shaper is one kind of heating up the plastic the plasticizing, pours into with the aid of the advancement organization the melting plastic in the mold cavity, after cooling, the stereotypia forms the product the plastic to take shape the processing equipment. It can dispose the different mold, but time takes shape the contour complex product, is in the plastic machinery one of main aircraft types. The plastic injection takes shape already has very many forms. The hydraulic pressure type plastic injection shaper is one of them, it mainly has gathers the mold organization, injects the part, the hydraulic transmission and the electricity control system and so on several parts of compositions, but the hydraulic pump, the hydraulic cylinder, each kind of hydraulic valve, the electrical machinery, the electrical part as well as the control measuring appliance are indispensable control part.The plastic injection shaper takes shape the cycle quickly by it, to each kind of plastic processing compatible, the size is precise as well as the automaticity higher merit, obtained the widespread use.Key word:Plastic injection shaper, hydraulic system, hydraulic pump, hydraulic cylinder, hydraulic valv目录摘要 (1)ABSTRACT (2)目录 (3)1 绪论 (5)1.1、塑料注射成型机概述 (5)1.2、注射成型机的工作原理 (6)1.3、技术要求及已知参数 (7)1.3.1对液压系统的要求 (8)1.3.2液压系统设计参数 (8)2. 250克塑料注射祝液压系统设计计算 (10)2.1液压执行元件载荷力和载荷转矩计算 (10)2.2.液压系统主要参数计算 (11)2.2.1初选系统工作压力 (11)2.2.2计算液压缸的主要结构尺寸 (12)2.2.3计算液压马达的排量 (13)2.2.4计算液压执行元件实际工作压力 (13)2.2.5计算液压执行元件实际所需流量 (13)2.3.制定系统方案和拟定液压系统图 (14)2.3.1制定系统方案 (14)2.3.2拟定液压系统图 (15)2.3.3液压元件的选择与设计 (24)2.4.液压系统性能验算 (31)2.4.1验算回路中的压力损失 (31)2.4.2液压系统发热温升计算 (33)2.4.3冷却器的计算 (36)3 系统使用维护说明书 (38)3.1. 注塑机温升过高五大危害 (38)3.2. 注塑机-原理和模式 (39)3.3. 注塑机-维护 (41)3.4. 预防性维修保养 (41)3.4.1液压油量 (42)3.4.2液压油温度 (42)3.4.3液压油油质 (42)3.4.4 滤油器清洗 (43)3.4.5冷却器清洗 (43)3.5. 注塑机电脑面板 (43)3.5.1电气部分 (43)3.5.2 机械部分 (45)3.6. 油温过高 (46)3.7. 噪音产生 (47)3.8. 保养简表 (48)设计分析 (49)设计心得 (50)致谢辞 (51)参考书目 (52)1 绪论1.1、塑料注射成型机概述塑料注射成型机（简称注塑机）是一种能将塑料加热塑化，借助螺杆（或柱塞）的推力，将塑料熔体射入闭合的模具型腔内，经冷却定型或固化后制成成品的塑料成型加工设备。