FL-5305S-HSS中文资料

爱色丽530分光密度计使用说明X-Rite 530 Spectrodensitometer Introduction无限色彩尽在掌握第一部分产品概述⏹爱色丽530分光密度计是当今功能最齐全，设计最新颖的手动颜色测量仪器。

⏹该仪器具有特殊设计的集成分光光度仪主芯片，保证您获得最准确、精确的测量数据。

⏹530分光密度计还配有最方便的按键和高清晰度的图像显示屏。

⏹制造商：美国爱色丽公司⏹主要功能：测量印刷品色墨的密度、颜色和网点面积等⏹主要部件：分光密度计、校准板、充电器仪器各部位介绍测量头电池电源开关校正白板数据线接口电源线接口（一）机身构件（二）按键名称及其功能向上跳位键：向上选择菜单项目。

向下跳位键：向下选择菜单项目。

X主目录键：取消当前修改，返回到主目录。

退出键：取消当前修改，返回到上一级菜单。

进入键：进入被选项目的子菜单；对修改进行确认。

（三）显示屏内主目录的结构主目录密度颜色匹配自动选择功能网点叠印印刷反差色调误差/灰度纸张指数比较校正配置（四）单个测量项目的界面T<选择测量数据形式>>V 0.28C 0.28M 0.28Y 0.29纸张样品标准选项密度减去标准设置相关选项滤波器类型或光源/视角用户对话框测量对象当前使用的功能测量数据说明：结合使用跳位键↑↓和进入键←，可以进入相关子目录进行设置。

日常校正的方法：每天使用仪器前应校正一次1.主目录> 校正，进入校正界面（如右上图）2.放平校正板（如右下图）3.把分光密度计放置在校正板上，测量孔对准圆形白板。

4.按下测量头，直到屏幕左下角显示“完成”，表示校正完成。

<测量白板>测量白板自动识别校正标准白板校正如何保管校正白板？放置于仪器包装套的底部，隔离光线照射，环境要干燥无尘。

全面校正的方法：当更换测量口径或偏振片的时候需要进行全面校正。

1.主目录> 配置>全面校正，进入全面校正界面（如右图）；2.先测量白板，仪器会提示测量两次；3.当屏幕提示“测量黑筒”时，将测量头对准房间中比较暗的地方，按住不放进行测量，直到仪器自动测量四次后才可松开；4.此时屏幕左下角显示“完成”，表示校正成功。

IRF5305HEXFET ® Power MOSFETPD - 91385BFifth Generation HEXFETs from International Rectifier utilize advanced processing techniques to achieve extremely low on-resistance per silicon area. This benefit,combined with the fast switching speed and ruggedized device design that HEXFET Power MOSFETs are well known for, provides the designer with an extremely efficient and reliable device for use in a wide variety of applications.The TO-220 package is universally preferred for all commercial-industrial applications at power dissipation levels to approximately 50 watts. The low thermal resistance and low package cost of the TO-220 contribute to its wide acceptance throughout the industry.ParameterMax.UnitsI D @ T C = 25°C Continuous Drain Current, VGS @ -10V -31ID @ T C = 100°C Continuous Drain Current, V GS @ -10V -22A I DMPulsed Drain Current -110P D @T C = 25°C Power Dissipation 110W Linear Derating Factor 0.71W/°C V GS Gate-to-Source Voltage± 20V E AS Single Pulse Avalanche Energy 280mJ I AR Avalanche Current-16A E AR Repetitive Avalanche Energy 11mJ dv/dt Peak Diode Recovery dv/dt -5.0V/ns T J Operating Junction and-55 to + 175T STGStorage Temperature RangeSoldering Temperature, for 10 seconds 300 (1.6mm from case )°CMounting torque, 6-32 or M3 srew10 lbf•in (1.1N•m)Absolute Maximum RatingsParameterTyp.Max.UnitsR θJC Junction-to-Case––– 1.4R θCS Case-to-Sink, Flat, Greased Surface 0.50–––°C/WR θJAJunction-to-Ambient–––62Thermal Resistancel Advanced Process Technology l Dynamic dv/dt Ratingl 175°C Operating Temperature l Fast Switching l P-ChannellFully Avalanche RatedDescription3/3/00IRF5305IRF5305IRF5305IRF5305IRF5305IRF5305IRF5305。

*******************************************************************************************************************************************************OPTOWA Y TECHNOLOGY INC. No .38, Kuang Fu S. Road, Hu Kou, Hsin Chu Industrial Park, Hsin Chu, Taiwan 3031550 nm DFB LASER DIODE MODULES DL-5300 SERIESUNCOOLED MQW DFB LD WITH PIGTAIL*******************************************************************************************************************************************************FEATURES² 1550 nm Uncooled Laser Diode with MQW Structure ² High Reliability, Long Operation Life² Single Frequency Operation with High SMSR ² 0 to 70o C operation without active cooling ² Build-in InGaAs monitorAPPLICATION Trunk Line, FitLDESCRIPTIONDL-5300 series are designed for coupling a single mode optical fiber with 1550 nm MQW DFB uncooled laser diode. DL-5300 series are the best kits as light sources for telecom and datacom applications.ELECTRICAL AND OPTICAL CHARACTERISTICS (T C =25 °C)Symbol ParameterTest ConditionsMin. Typ. Max. Unit I th Threshold Current CW10 15 mA V OP Operating V oltage CW, I F = I th +20mA 1.2 1.5 V P fOptical Output Power Part No:DL-530X DL-531X DL-532X DL-533X CW, I F = I th +20mA0.2 0.5 1.0 2.0 - - - - - - mWλc Center WavelengthCW, Po= P f1530 1550 1570 nm SMSR Side Mode Suppression Ratio CW, I th +20mA 30 35 dB t r , t f Rise And Fall Times I F =I th , I th +20mA , 20~ 80% 0.226 ns ΔP f / P f Tracking Error APC, 0~+70 ºC - - ±1.5 dB I m PD Monitor Current CW, I th +20mA ,V RD =1V 100 μA I DPD Dark CurrentV RD =5V0.1μAC tPD CapacitanceV RD =5V , f=1MHz10 15 pFABSOLUTE MAXIMUM RATINGS (T C =25 ºC)Symbol ParameterRatings Unit P o Optical Output Power (530X/531X/532X/533X) 0.5/1.0/1.5/3mW V RL LD Reverse V oltage 2 V V RD PD Reverse V oltage 10 V I FD PD Forward Current 1.0 mA T opr Operating Temperature 0 to 70 ºC T stgStorage Temperature-40~+85ºC*******************************************************************************************************************************************************OPTOWA Y TECHNOLOGY INC. No .38, Kuang Fu S. Road, Hu Kou, Hsin Chu Industrial Park, Hsin Chu, Taiwan 303MECHANICAL DIMENSION (mm) and PIN ASSIGNMENTNote: Specifications subject to change without notice.ORDER INFORMATIONPart No.: D L − 5 3 □ □。

IRF5305S/LHEXFET ® Power MOSFETPD - 91386ClAdvanced Process Technology l Surface Mount (IRF5305S)l Low-profile through-hole (IRF5305L)l 175°C Operating Temperature l Fast Switching l P-Channell Fully Avalanche Rated4/1/99Absolute Maximum RatingsFifth Generation HEXFETs from International Rectifier utilize advanced processing techniques to achieve extremely low on-resistance per silicon area. This benefit, combined with the fast switching speed and ruggedized device design that HEXFET Power MOSFETs are well known for, provides the designer with an extremely efficient and reliable device for use in a wide variety of applications.The D 2Pak is a surface mount power package capable of accommodating die sizes up to HEX-4. It provides the highest power capability and the lowest possible on-resistance in any existing surface mount package. The D 2Pak is suitable for high current applications because of its low internal connection resistance and can dissipate up to 2.0W in a typical surface mount application.The through-hole version (IRF5305L) is available for low-profile applications.Description2 D PakT O -262ParameterTyp.Max.UnitsR θJC Junction-to-Case––– 1.4R θJAJunction-to-Ambient ( PCB Mounted,steady-state)**–––40Thermal Resistance°C/WParameterMax.UnitsI D @ T C = 25°C Continuous Drain Current, V GS @ -10V -31I D @ T C = 100°C Continuous Drain Current, V GS @ -10V -22A I DMPulsed Drain Current -110P D @T A = 25°C Power Dissipation 3.8W P D @T C = 25°C Power Dissipation 110W Linear Derating Factor 0.71W/°C V GS Gate-to-Source Voltage± 20V E AS Single Pulse Avalanche Energy 280mJ I AR Avalanche Current-16A E AR Repetitive Avalanche Energy 11mJ dv/dt Peak Diode Recovery dv/dt -5.8V/ns T J Operating Junction and-55 to + 175T STGStorage Temperature RangeSoldering Temperature, for 10 seconds300 (1.6mm from case )°CIRF5305S/LIRF5305S/LIRF5305S/LIRF5305S/LIRF5305S/LIRF5305S/LIRF5305S/LIRF5305S/LIRF5305S/L。

B-51MEDIDORES DE VAZÃO EM LINHAPara Água e ArU L eitura Direta em GPM, LPM, SCFM e SLPM U Escalas para Ar e Água U F luidos São Sempre Visualizados U Monta em Qualquer Posição U F ácil de Limpar e PreservarU Exatidão de ±5% FE FL-510 mostrado emescala menor que a real.Os medidores de vazão em linhada Série FL-500 possuem uma construção robusta, são fáceis de instalar e fazem uma leitura direta da taxa de vazão para água e ar a pressões atmosféricas e de 90 psi.Para uma maior versatilidade, os medidores de vazão da Série FL-500 podem ser pedidos com interruptores de proximidade elétrica (pedirseparadamente, consulte a próxima página) para taxas de vazão de sinal específico. As configurações são facilmente ajustáveis com uma chave de fenda.ESPECiFiCAçõESExatidão: ±5% FE Construção:Tubo e Flutuador de Fluxo: PVC P artes Úmidas internas:Encaixes de extremidades de 316 de aço inoxidávelVedações NPT Fêmea, Latão: FKM Serviço Líquido: 200 psig a 21°C (70°F)Serviço de Gás: 100 psig a 21°C (70°F)Temperatura Máxima: 66°C (150°F) a 25 psigQueda de Pressão: 4 psig FEDimensões: 177,8 mm (7") de comprimento F L-505 através de FL-515: Diâmetro de 50,8 mm (2") F L-530 através de FL-550: Diâmetro de 76,2 mm (3")Série FL-500Para corpo e flutuador de polisulfone, adicione o sufixo “-PLSF” ao número do modelo, para informações sobre o preço, consulte o Departamento de Engenharia de Vazão.† Para o certificado NIST rastreável (somente para água), acrescente o sufixo “-NIST” ao número do modelo, sob um custo adicional.Exemplo de pedido: FL-515, medidor de vazão 1 FNPT , 15 GPM, 135 SCFM.FL-550, medidor de vazão 11⁄2 FNPT, 50 GPM, 500 SCFM no máx.FL-530 mostrado em escala menor que a real.FL-510, mostrado em escala maior que a real.†。

Power MOSFETIRF530, SiHF530Vishay SiliconixFEATURES•Dynamic dV/dt Rating•Repetitive Avalanche Rated •175 °C Operating Temperature •Fast Switching •Ease of Paralleling•Simple Drive Requirements •Lead (Pb)-free AvailableDESCRIPTIONThird generation Power MOSFETs from Vishay provide the designer with the best combination of fast switching,ruggedized device design, low on-resistance and cost-effectiveness.The TO-220 package is universally preferred for all commercial-industrial applications at power dissipation levels to approximately 50 W. The low thermal resistance and low package cost of the TO-220 contribute to its wide acceptance throughout the industry.Notesa.Repetitive rating; pulse width limited by maximum junction temperature (see fig. 11).b.V DD = 25 V, starting T J = 25 °C, L = 528 µH, R G = 25 Ω, I AS = 14 A (see fig. 12).c.I SD ≤ 14 A, dI/dt ≤ 140 A/µs, V DD ≤ V DS , T J ≤ 175 °C.d. 1.6 mm from case.PRODUCT SUMMARYV DS (V)100R DS(on) (Ω)V GS = 10 V0.16Q g (Max.) (nC)26Q gs (nC) 5.5Q gd (nC)11ConfigurationSingleTO-220GDSORDERING INFORMATIONPackage TO-220Lead (Pb)-free IRF530PbF SiHF530-E3 SnPbIRF530SiHF530ABSOLUTE MAXIMUM RATINGS T C = 25 °C, unless otherwise notedARAMETER SYMBOL LIMIT UNIT Drain-Source Voltage V DS100VGate-Source Voltage V GS ± 20 Continuous Drain Current V GS at 10 VT C = 25 °C I D14A T C = 100 °C10Pulsed Drain Current a I DM 56Linear Derating Factor0.59W/°C Single Pulse Avalanche Energy b E AS 69mJ Repetitive Avalanche Current a I AR 14 A Repetitive Avalanche Energy a E AR 8.8mJ Maximum Power Dissipation T C = 25 °CP D 88WPeak Diode Recovery dV/dt cdV/dt 5.5V/ns Operating Junction and Storage Temperature Range T J , T stg- 55 to + 175°C Soldering Recommendations (Peak Temperature)for 10 s 300d Mounting Torque6-32 or M3 screw10 lbf · in 1.1N · m * Pb containing terminations are not RoHS compliant, exemptions may applyIRF530, SiHF530Vishay SiliconixNotesa.Repetitive rating; pulse width limited by maximum junction temperature (see fig. 11).b.Pulse width ≤ 300 µs; duty cycle ≤ 2 %.THERMAL RESISTANCE RATINGSARAMETER SYMBOL TY.MAX.UNITMaximum Junction-to-Ambient R thJA -62°C/W Case-to-Sink, Flat, Greased Surface R thCS 0.50-Maximum Junction-to-Case (Drain)R thJC- 1.7IRF530, SiHF530Vishay Siliconix TYPICAL CHARACTERISTICS 25 °C, unless otherwise notedFig. 1 - Typical Output Characteristics, T C= 25 °C Fig. 2 - Typical Output Characteristics, T C= 175 °CFig. 3 - Typical Transfer CharacteristicsFig. 4 - Normalized On-Resistance vs. TemperatureIRF530, SiHF530 Vishay SiliconixFig. 5 - Typical Capacitance vs. Drain-to-Source VoltageFig. 6 - Typical Gate Charge vs. Gate-to-Source VoltageFig. 7 - Typical Source-Drain Diode Forward VoltageFig. 8 - Maximum Safe Operating AreaIRF530, SiHF530Vishay SiliconixFig. 9 - Maximum Drain Current vs. Case Temperature Fig. 10a - Switching Time Test CircuitFig. 10b - Switching Time WaveformsFig. 11 - Maximum Effective Transient Thermal Impedance, Junction-to-CaseFig. 12a - Unclamped Inductive Test CircuitFig. 12b - Unclamped Inductive WaveformsIRF530, SiHF530Vishay SiliconixFig. 12c - Maximum Avalanche Energy vs. Drain CurrentFig. 13a - Basic Gate Charge WaveformFig. 13b - Gate Charge Test CircuitIRF530, SiHF530Vishay Siliconix Array Fig. 14 - For N-ChannelVishay Siliconix maintains worldwide manufacturing capability. Products may be manufactured at one of several qualified locations. Reliability data for Silicon Technology and Package Reliability represent a composite of all qualified locations. For related documents such as package/tape drawings, part marking, andreliability data, see /ppg?91019.Disclaimer Legal Disclaimer NoticeVishayAll product specifications and data are subject to change without notice.Vishay Intertechnology, Inc., its affiliates, agents, and employees, and all persons acting on its or their behalf (collectively, “Vishay”), disclaim any and all liability for any errors, inaccuracies or incompleteness contained herein or in any other disclosure relating to any product.Vishay disclaims any and all liability arising out of the use or application of any product described herein or of any information provided herein to the maximum extent permitted by law. The product specifications do not expand or otherwise modify Vishay’s terms and conditions of purchase, including but not limited to the warranty expressed therein, which apply to these products.No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document or by any conduct of Vishay.The products shown herein are not designed for use in medical, life-saving, or life-sustaining applications unless otherwise expressly indicated. Customers using or selling Vishay products not expressly indicated for use in such applications do so entirely at their own risk and agree to fully indemnify Vishay for any damages arising or resulting from such use or sale. Please contact authorized Vishay personnel to obtain written terms and conditions regarding products designed for such applications.Product names and markings noted herein may be trademarks of their respective owners.元器件交易网。

1270 nm ~ 1610 nm DFB LD MODULES DL-5300S-CXX0 Series 2.5 Gbps CWDM MQW-DFB LD PIGTAIL******************************************************************************************************************************************************* FEATURES² 18-wavelength CWDM: from 1270 nm to 1610 nm, each Step 20 nm² High reliability, long operation life² 0 ºC ~+70 ºC operation² Speed up to 2.5 Gbps² Single frequency operation with high SMSR² Build-in InGaAs monitorAPPLICATIONOC-3, OC-12, OC-48 and Gigabit CWDM Optical communication systemDESCRIPTIONDL-5300S-CXX0 series are MQW-DFB laser diodes that provide a durable, single frequency oscillation with emission wavelength from 1270 nm to 1610 nm CWDM, each step 20nm.ELECTRICAL AND OPTICAL CHARACTERISTICS (T C=25 °C)Symbol Parameter Test Conditions Min. Typ. Max. Unit I th Threshold Current CW 10 20 mAI OP Operating Current CW, I th+20mA 35 50 mAV OP Operating V oltage CW, I th+20mA 1.2 1.5 VP f Optical Output PowerPart No: DL-532XS- CXX0DL-533XS- CXX0 CW, I F= I th+20mA1.02.0-- mWλc Center Wavelength CW, I th+20mA λ-3λλ+2nm SMSR Side Mode Suppression Ratio CW, I th+20mA 30 35 dBt r, t f Rise And Fall Times I F=I th, I th+20mA,20~ 80% 150 psΔP f / P f Tracking Error APC, 0~+70 ºC - - ±1.5 dBI m PD Monitor Current CW, I th+20mA,V RD=1V 50 μAI D PD Dark Current V RD=5V 10 nAC t PD Capacitance V RD=5V, f=1MHz 10 15 pF Note: Central CWDM wavelength is from 1270 nm to 1610 nm, each step 20 nm.ABSOLUTE MAXIMUM RATINGS (T C=25 ºC)Symbol Parameter Ratings UnitP o Optical Output Power (532XS/533XS) 1.5/3 mWV RL LD Reverse V oltage 2 VV RD PD Reverse V oltage 10 VI FD PD Forward Current 1.0 mAT opr Operating Temperature 0~+70 ºCT stg Storage Temperature -40~+85 ºC****************************************************************************************************************************************************************************************************************************************************************************************************************ORDER INFORMATION−。

1s DescriptionThe FA5304AP(S) and FA5305AP(S) are bipolar ICs forswitching power supply control and can directly drive a power MOSFET. These ICs contain many functions in a small 8-pin package. With these ICs, a high-performance power supply can be created compactly because not many external components are needed.s Features•Drive circuit for connecting a power MOS-FET (I O = ±1.5A)•Wide operating frequency range (5 to 600kHz)•Pulse-by-pulse overcurrent limiting function Positive voltage detection: FA5304AP(S)Negative voltage detection: FA5305AP(S)•Overload cutoff function (Latch or non-protection mode selectable)•Output ON/OFF control function by external signals •Overvoltage cutoff function in latch mode•Undervoltage malfunction prevention function (ON at 16V and OFF at 8.7V)•Error amplifier for control by tertiary winding detection •Low standby current (90µA typ.)•8-pin package (DIP/SOP)s Applications•Switching power supply for general equipments Dimensions, mm SOP-8DIP-80˚05FA5304AP(S)/FA5305AP(S)2s Block diagram FA5304AP(S)Pin Pin DescriptionNo.symbol1IN (–)Inverting input to error amplifier 2FB Error amplifier output 3IS (+)Overcurrent (+) detection 4GND Ground 5OUT Output 6VCC Power supply7CT Oscillator timing capacitor 8CSSoft-start and ON/OFF controlFA5305AP(S)PinPin DescriptionNo.symbol1IN (–)Inverting input to error amplifier 2FB Error amplifier output 3IS (–)Overcurrent (–) detection 4GND Ground 5OUT Output 6VCC Power supply7CT Oscillator timing capacitor 8CSSoft-start and ON/OFF controlFA5304AP(S)/FA5305AP(S)3s Absolute maximum ratingsCommon to FA5304AP(S) and FA5305AP(S)ItemSymbolRating Unit V CC 30V I O ±1.5A V IN 4V V FB 4V V IS –0.3 to +4V I CS 2mA P d 800 (DIP-8) *1mW 550 (SOP-8) *2T opr –30 to +85°C T stg–40 to +150°Cs Recommended operating conditions Common to FA5304AP(S) and FA5305AP(S)ItemSymbolMin.Max.Unit Supply voltage V CC 1030V Error amplifier feedback resistor R NF100k ΩSoft-start capacitor C S 0.11µF Oscillation frequencyf OSC5600kHzSupply voltage Output current Error amplifier input voltageFeedback terminal input voltage Overcurrent detection terminal input voltage CS terminal input current Total power dissipation (Ta = 25°C)Operating temperature Storage temperatureNotes:*1Derating factor Ta > 25°C : 8.0mW/°C ( on PC board )*2Derating factor Ta > 25°C : 5.5mW/°C ( on PC board )s Electrical characteristics (Ta=25°C, V CC =18V,fosc=135kHz)Oscillator sectionCommon to FA5304AP(S) and FA5305AP(S)ItemSymbolTest conditionMin.Typ.Max.Unit Oscillation frequencyf OSC C T = 360pF112135148kHz Frequency variation 1 (due to supply voltage change)f dv V CC = 10 to 30V ±1%Frequency variation 2 (due to temperature change)f dTT a = –30 to +85°C±4%Error amplifier sectionCommon to FA5304AP(S) and FA5305AP(S))ItemSymbolTest conditionMin.Typ.Max.Unit Reference voltage V B 1.90 2.00 2.10V Input bias current I B V 1 = 2V–500–50nA Open-loop voltage gain A V 80dB Unity-gain bandwidthf T1.0MHz Maximum output voltage (Pin 2)V OM+R NF = 100k Ω2.70VV OM–R NF = 100k Ω200mVOutput source current (Pin 2)I MO+V OM = 1V–100–50µAPulse width modulation circuit sectionCommon to FA5304AP(S) and FA5305AP(S)ItemSymbolTest condition Min.Typ.Max.Unit Input threshold voltage (Pin 2)V TH FBO Duty cycle = 0%0.80 1.00 1.20V V TH FBM Duty cycle = D MAX1.70 1.902.10V Maximum duty cycleD MAX424550%Soft-start circuit sectionCommon to FA5304AP(S) and FA5305AP(S)ItemSymbolTest condition Min.Typ.Max.UnitCharge current (Pin 8)I CHGPin 8 = 0V –15–10–5µA Input threshold voltage (Pin 8)V TH CSO Duty cycle = 0%0.80 1.00 1.20V V TH CSMDuty cycle = D MAX1.701.902.10VFA5304AP(S)/FA5305AP(S)Overcurrent limiting circuit sectionItem Symbol Test condition FA5304AP(S)FA5305AP(S)UnitMin.Typ.Max.Min.Typ.Max. Input threshold voltage (Pin 3)V TH IS0.200.240.28–0.20–0.17–0.14V Overcurrent detection terminal source current I IS Pin 3 = 0V–300–200–100–240–160–80µA Delay time T PD IS150200nsLatch-mode cutoff circuit section Common to FA5304AP(S) and FA5305AP(S)Item Symbol Test condition Min.Typ.Max.Unit CS terminal sink current I SINK CS Pin 8 = 6V, Pin 2 = 1V4070150µA Cutoff threshold voltage (Pin 8)V TH CS 6.57.07.5VOverload cutoff circuit section Common to FA5304AP(S) and FA5305AP(S)Item Symbol Test condition Min.Typ.Max.Unit Cutoff threshold voltage (Pin 2)V TH FB 2.5 2.7 2.9VUndervoltage lock-out circuit section Common to FA5304AP(S) and FA5305AP(S)Item Symbol Test condition Min.Typ.Max.Unit OFF-to-ON threshold voltage V TH ON15.516.016.5V ON-to-OFF threshold voltage V TH OFF8.208.709.20V Voltage hysteresis V HYS7.30VOutput section Common to FA5304AP(S) and FA5305AP(S)Item Symbol Test condition Min.Typ.Max.Unit L-level output voltage V OL I O = 100mA 1.30 1.80VH-level output voltage V OH I O = –100mA, V CC = 18V16.016.5V Rise time tr No load50ns Fall time tf No load50nsOutput ON/OFF control circuit section Common to FA5304AP(S) and FA5305AP(S)Item Symbol Test condition Min.Typ.Max.Unit CS terminal source current I SOURCE CS Pin 8 = 0V–15–10–5µA OFF-to-ON threshold voltage (Pin 8)V TH ON CS pin voltage0.560.76V ON-to-OFF threshold voltage (Pin 8)V TH OFF CS pin voltage0.300.42VOverall device Common to FA5304AP(S) and FA5305AP(S)Item Symbol Test condition Min.Typ.Max.Unit Standby current I CC ST V CC = 14V90150µA Operating-state supply current I CC OP915mA OFF-state supply current I CC OFF 1.1 1.8mA Cutoff-state supply current I CCL 1.1 1.8mA45FA5304AP(S)/FA5305AP(S)Fig. 1 Configuration with error amplifierFig. 2 Configuration with optocoupler (FB pin input)Fig. 3 PWM comparatorFig. 4 PWM comparator timing charts Description of each circuit1. Oscillator (See block diagram on page 8.)The oscillator generates a triangular waveform by charging and discharging a capacitor. CT pin voltage oscillates between an upper limit of approx. 3.0V and a lower limit of approx. 1.0V. The oscillation frequency is determined by a external capacitance C T connected to CT pin, and approximately given by the following equation: (1)The recommended oscillation range is between 5k and 600kHz.The oscillator output is connected to a PWM comparator.2. Feedback circuitFigure 1 gives an example of connection in which built-in error amplifier is used to couple the feedback signal to IN(-) pin. Let n 2be the number of turns of secondary winding L 2 and n 3 be the number of turns of tertiary winding L 3. V CC and Vout are given by Vcc= 2(V)•(R 1+R 2)/R 2....................................(2)V OUT ȃ(n 2/n 3)•(Vcc+V D3)–V D2 (3)(where V D2 and V D3 are the forward voltage drops across diodes D 2and D 3 respectively).Here, the following equation must be satisfied to prevent from the malfunction of OUT pin at shutdown.(R1•R2)/ (R1+R2) 11k Ω (4)Figure 2 gives an example of connection in which anoptocoupler is used to couple the feedback signal to the FB pin. If this circuit causes power supply instability, the frequency gain can be decreased by connecting R 4 and C 4 as shown in figure 2. R 4 should be between several tens of ohms toseveral kiloohms and C 4 should be between several thousand picofarads to one microfarads.3. PWM comparatorThe PWM comparator has four inputs as shown in Figure 3.Oscillator output x is compared with CS pin voltage , FB pin , and DT voltage {. The lowest of three inputs , , and {is compared with output x . If it is lower than the oscillator output, the PWM comparator output is high, and if it is higher than the oscillator output, the PWM comparator output is low (see Fig. 4).The IC output voltage is high during when the comparator output is low, and the IC output voltage is low during when the comparator output is high.When the IC is powered up, CS pin voltage controls soft start operation. The output pulse then begins to widengradually. During normal operation, the output pulse width is determined within the maximum duty cycle (FA5304A,FA5305A: 45%) set by DT voltage { under the condition set by feedback signal , to stabilize the output voltage.C T (pF)f (kH Z ) =4.8 • 1046FA5304AP(S)/FA5305AP(S)4. CS pin circuitAs shown in Figure 5, capacitor C S is connected to the CS pin.When power is turned on, the constant current source (10µA)begins to charge capacitor C S . Accordingly, the CS pin voltage rises as shown in Figure 6. The CS pin is connected to an input of the PWM comparator. The device is in soft-start mode while the CS pin voltage is between 1.0V and 1.9V common to FA5304A and FA5305A. During normal operation, the CS pin is clamped at 3.6V by internal zener diode Zn. If the output voltage drops due to an overload, etc., the clamp voltage shifts from 3.6V to 8.0V. As a result, the CS pin voltage rises to 8.0V.The CS pin is also connected to latch comparator C2. If the pin voltage rises above 7.0V, the output of comparator C2 goes high to turn off the bias circuit , thereby shutting the output down. Comparator C2 can be used not only for shutdown in response to an overload, but also for shutdown in response to an overvoltage. Comparator C1 is also connected to the CS pin, and the bias circuit is turned off and the output is shut down if the CS pin voltage drops below 0.42V. In this way,comparator C1 can also be used for output on/off control.As explained above, the CS pin can be used for soft-start operation, overload and overvoltage output shutdown and output on/off control.Further details on the four functions of the CS pin are given below.4.1 Soft start functionFigure 7 shows the soft start circuit. Figure 8 is the soft-start operation timing chart. The CS pin is connected to capacitor C S . When power is turned on, a 10µA constant-current source begins to charge the capacitor. As shown in the timing chart,the CS pin voltage rises slowly in response to the charging current. The CS pin is connected internally to the PWM comparator. The comparator output pulse slowly widens as shown in the timing chart.The soft start period can be approximately evaluated by the period ts from the time the IC is activated to the time the output pulse width widens to 30%. Period ts is given by the following equation:t S (m S ) = 160C S (µF) (2)Fig. 5 CS pin circuitFig. 6 CS pin waveformFig. 7 Soft-start circuitFig. 8 Soft-start timing chart7FA5304AP(S)/FA5305AP(S)4.2 Overload shutdownFigure 9 shows the overload shutdown circuit, and Figure 10 is a timing chart which illustrates overload shutdown operation.If the output voltage drops due to an overload or short-circuit, the output voltage of the FB pin rises. If FB pin voltage exceeds the reference voltage (2.7V) of comparator C3, the output of comparator C3 switches low to turn transistor Q off. In normal operation, transistor Q is on and the CS pin is clamped at 3.6V by zener diode Zn. With Q off, the clamp is released and the 10µA constant-current source begins to charge capacitor C S again and the CS pin voltage rises. When the CS pin voltage exceeds the reference voltage (7.0V) of comparator C2, the output of comparator C2 switches high to turn the bias circuit off. The IC then enters the latched mode and shuts the output down. Shutdown current consumption is 400µA(V CC =9V).This current must be supplied through the startup resistor. The IC then discharges the MOSFET gates.Shutdown operation initiated by an overload can be reset by lowering supply voltage V CC below 8.7V or forcing the CS pin voltage below 7.0V.The period t OL from the time that the output is short-circuited to the time that the bias circuit turns off is given by the following equation:t OL (m S ) = 340Cs(µF) (3)4.3 Overvoltage shutdownFigure 11 shows the overvoltage shutdown circuit, and Figure 12 is a timing chart which illustrates overvoltage shutdown operation.The optocoupler PC1 is connected between the CS and V CC pins. If the output voltage rises too high, the PC1 turns on to raise the voltage at the CS pin via resistor R 6. When the CS pin voltage exceeds the reference voltage (7.0V) ofcomparator C2, comparator C2 switches high to turn the bias circuit off. The IC then enters the latched mode and shuts the output down. The shutdown current consumption of the IC is 400µA(V CC =9V). This current must be applied via startup resistor R 5.The IC then discharges the MOSFET gates.The shutdown operation initiated by an overvoltage condition can be reset by lowering supply voltage V CC below 8.7V or forcing the CS pin voltage below 7.0V.During normal operation, the CS pin is clamped by a 3.6V zener diode with a sink current of 150µA max. Therefore, a current of 150µA or more must be supplied by the optocoupler in order to raise the CS pin voltage above 7.0V.Fig. 9 Overload shutdown circuitFig. 10 Overload shutdown timing chartFig. 11 Overvoltage shutdown circuitFig. 12 Overvoltage shutdown timing chart8FA5304AP(S)/FA5305AP(S)4.4 Output ON/OFF controlThe IC can be turned on and off by an external signal applied to the CS pin.Figure 13 shows the external output on/off control circuit, and Figure 14 is the timing chart.The IC is turned off if the CS pin voltage falls below 0.42V. The output of comparator C1 switches high to turn the bias circuit off. This shuts the output down. The IC then discharges the MOSFET gates.The IC turns on if the CS pin is opened for automatic soft start.The power supply then restarts operation.5. Overcurrent limiting circuitThe overcurrent limiting circuit detects the peak value of every drain current pulse of the main switching MOSFET to limit the overcurrent.The detection threshold is +0.24V for FA5304A with respect to ground as shown in Figure 15.The drain current of the MOSFET is converted to voltage by resistor R 7 and fed to the IS pin of the IC. If the voltage exceeds the reference voltage (0.24V) of comparator C4, the output of comparator C4 goes high to set flip-flop output Q high. The output is immediately turned off to shut off the current. Flip-flop output Q is reset on the next cycle by the output of the PWM comparator to turn the output on again. This operation is repeated to limit the overcurrent.If the overcurrent limiting circuit malfunctions due to noise,place an RC filter between the IS pin and the MOSFET.Figure 16 is a timing chart which illustrates current-limiting operations.Fig. 13 External output on/off control circuitFig. 14 Timing chart for external output on/off controlFig. 16 Overcurrent timing chart for FA5304AFig. 15 Overcurrent limiting circuit for FA5304A9FA5304AP(S)/FA5305AP(S)The detection threshold is -0.17v for FA5305A with respect to ground as shown in Figure 17.The operation is similar to that of FA5304A except the threshold is minus voltage compared to that which is plus voltage for FA5304A.Figure 18 is a timing chart which illustrates current limiting operations.6. Undervoltage lockout circuitThe IC incorporates a circuit which prevents the IC from malfunctioning when the supply voltage drops. When the supply voltage is raised from 0V, the IC starts operation with V CC =16.0V.If the supply voltage drops, the IC shuts its output down when V CC =8.7V. When the undervoltage lockout circuit operates, the CS pin goes low to reset the IC.7. Output circuitAs shown in Figure 19, the IC’s totem-pole output can directly drive the MOSFET. The OUT pin can source and sink currents of up to 1.5A.If IC operation stops when the undervoltage lockout circuit operates, the gate voltage of the MOSFET goes low and the MOSFET is shut down.Fig. 17 Overcurrent limiting circuit for FA5305AFig. 18 Overcurrent timing chart for FA5305AFig. 19 Output circuitOUT pin outputLComparator C4ReferenceOvercurrent limitingMinus detectionFA5304AP(S)/FA5305AP(S)10s Design advice1. Startup circuitIt is necessary to start-up IC that the voltage inclination of VCC terminal “dVcc/dt” satisfies the following equation(4).dVcc/dt(V/s)>1.8/(Cs(µF)) (4)Cs : capacitor connected between CS terminal and GNDNote that equation (4) must be satisfied in any condition. Also,it is necessary to keep “latch mode” for overload protection or overvoltage protection that the current supplied to VCC terminal through startup resistor satisfies the following equation(5).Icc(Lat)>0.4mA for Vcc9.2V (5)Icc(Lat): Cutoff-state(=Latch mode) supply currentThe detail is explained as follows.(1) Startup circuit connected to AC line directlyFig. 20 shows a typical startup circuit that a startup resistor Rc is connected to AC line directly. The period from power-on to startup is determined by Rc, R D and C A . Rc, R D and C A must be designed to satisfy the following equations.dVcc/dt(V/s)=(1/C A ) • {(V AVE –Vccon )/R C –Vccon/R D –Iccst} >1.8/(Cs(µF)) (6)Rc(k Ω)< (V AVE –9.2(V))/{0.4 (mA) + (9.2(V)/R D (k Ω) } (7)V AVE = Vac • ǰ2/π: Average voltage applied to AC line side of Rc Vac:AC input effective voltageVccon:ON threshold of UVLO, 16.5V(max.)Iccst:Standby current, 0.15 mA(max.)In this method, Vcc voltage includes ripple voltage influenced by AC voltage. Therefore, enough dVcc/dt required byequation (6) tend to be achieved easily when Vcc reaches to Vccon even if Vcc goes up very slowly.After power-off, Vcc does not rise up because a voltageapplied from bias winding to VCC terminal decreases and the current flowing R C becomes zero, therefore, re-startup does not occur after Vcc falls down below OFF threshold of UVLO until next power-on.Fig. 20 Startup circuit example(1)11(2) Startup circuit connected to rectified lineThis method is not suitable for FA5304A and FA5305A,especially concerned with re-startup operation just after power-off or startup which AC input voltage goes up slowly. Fig. 21shows a startup circuit that a startup resistor R A is connected to rectified line directly.The period from power-on to startup is determined by R A , R B and C A . R A , R B and C A must be designed to satisfy the following equations.dVcc/dt(V/s)=(1/C A )•{( V IN –Vccon )/R A – Vccon/R B –Iccst } >1.8/(Cs(µF)) (8)R A (k Ω)< (V IN – 9.2(V))/{0.4(mA) + (9.2(V)/R B (k Ω))}..............(9)V IN : ǰ2 •(AC input effective voltage)After power-off, once V CC falls down below OFF threshold voltage, V CC rises up again and re-startup occurs while the capacitor C 1 is discharged until approximately zero because V CC voltage rises up by the current flowing R A .This operation is repeated several times.After the repeated operation, IC stops in the condition that V CC voltage is equal to Vccon (=ON threshold) because capacitor C 1 is discharged gradually and the decreased V CC inclination is out of the condition required by equation (4).After that, re-startup by power-on can not be guaranteed even when equation (8) is satisfied. The image of that the startup is impossible is shown in Fig. 22. It is necessary to startup IC that supply current Icc (startup) to VCC is over 4mA in the condition of Tj < 100 °C during Vcc is kept at Vccon(Լ16V,balance state at Vccon after the repeated operation.Icc (start-up) > 4mA (10)at Vcc=Vccon, Tj<100°C, after power-offThis balance state that startup is impossible tends to occur at higher temperature.If power-on is done when Vcc is not kept at Vccon (forexample: power-off is done and after enough time that C 1 is discharged until Vcc can not be pulled up to Vccon), the IC can startup in the condition given by equation(8).In some cases, such as when the load current of power supply is changed rapidly, you may want to prolong the hold time of the power supply output by means of maintaining Vcc over the off threshold.For this purpose, connect diode D 4 and electrolytic capacitor C 4 as shown in Fig. 23. This prolongs the hold time of thepower supply voltage Vcc regardless of the period from power-on to startup.Fig. 21 Startup circuit example(2)Fig. 23 Startup circuit example(3)Startup is impossible (dVcc/dt <1.8/Cs just before Vcc reaches Vccon).Icc>4mA is necessary for startup atFig. 22 Image of Vcc waveform when re-startup is impossible122. Disabling overload shutdown functionAs shown in Figure 24, connect a 330k Ω to 470k Ω resistor between the CS pin and ground. Then, the CS pin voltage does not rise high enough to reach the reference voltage (7.0V) of the latch comparator, and the IC does not enter the OFF latch mode. With this connection, the overvoltage shutdown function is not available.3. Setting soft start period and OFF latch delay independentlyFigure 25 shows a circuit for setting the soft start period and OFF latch delay independently. In this circuit, capacitance C S determines the soft start period, and capacitance C Ldetermines the OFF latch delay. If the overload shutdown and overvoltage shutdown functions raise the CS pin voltage to around 5V, zener diode Zn becomes conductive to charge C L .The OFF latch delay can be thus prolonged by C L .4. Laying out Vcc and ground linesFigure 26 and Figure 27 show the recommended layouts of V CC and ground lines. The bold lines represent paths carrying large currents. The lines must have an adequate thickness.5. Sink current setting for CS terminalA sink current to CS terminal must be satisfied the following condition to prevent from the malfunction which uncontrolled pulse output generates at OUT terminal when latch-mode protection should be operated for overvoltage.150µA < Ics(sink) < 500µA at Vcs= 6.5(V)Ics(sink): Sink current to CS terminalExample (for the circuit shown in Fig. 28 )Ics(sink) = (28(V)–18(V)– 6.5(V))/7.5(k Ω) Լ 467 (µA) < 500 (µA)Fig. 25 Independent setting of soft-start period and OFF latchdelayFig. 26 Vcc line and ground line for FA5304AFig. 24 Disabling overload shutdown functionFig. 27 Vcc line and ground line for FA5305AFig. 28 Setting sink current for CS terminal13s Characteristic curves (Ta = 25°C)Oscillation frequency (f OSC ) vs.Oscillation frequency (f OSC ) vs.timing capacitor capacitance (C T )ambient temperature (Ta)Output duty cycle vs. FB terminal voltage (V FB )Output duty cycle vs. FB terminal source current (Isource)Output duty cycle vs. CS terminal voltage (V CS )H-level output voltage (V OH ) vs.output source current (I SOURCE)14L-level output voltage (V OL ) vs.IS (+) terminal threshold voltage (V TH IS(+)) vs.output sink current (I SINK )ambient temperature (Ta)FA5304AP(S)IS (–) terminal threshold voltage (V TH IS(–)) vs.IS (+) terminal current (I IS(+)) vs.ambient temperature (Ta)IS (+) terminal voltage (V IS(+))FA5305AP(S)FA5304AP(S)IS (–) terminal current (I IS(–)) vs.CS terminal sink current (I SINK CS ) vs.IS (–) terminal voltage (V IS(–))CS terminal voltage (V CS )FA5305AP(S)V O L [V ]I SINK [A]15Error amplifier frequency (f) vs. voltage gain (Av) /phase (θ)Supply current (I CC ) vs. supply voltage (V CC )Normal operationSupply current (I CC ) vs. supply voltage (V CC )OFF or OFF latch mode16s Application circuitExample of FA5304AP(S) application circuit (1)Example of FA5304AP(S) application circuit (2)。

1310 nm LASER DIODE MODULESUNCOOLED MQW-FP LD WITH PIGTAIL******************************************************************************************************************************************************* FEATURES² 1310 nm typical emission wavelength² P f >= 3mW @Ith+20 mA² High reliability, long operation life² High temperature operation without active cooling² Build-in InGaAs monitorAPPLICATIONTrunk Line, FitLDESCRIPTIONFL-3300 series are designed for coupling a single mode optical fiber with 1310 nm MQW-FP uncooled laser diode. FL-3300 series are the best kits as light sources for telecom and datacom applications. ELECTRICAL AND OPTICAL CHARACTERISTICS (T C=25 °C)Symbol Parameter Test Conditions Min. Typ. Max. UnitI th Threshold Current CW 12 15 mAV OP Operating V oltage CW, I F= I th+20mA 1.2 1.5 VP f Optical Output Power CW, I F= I th+20mA 3.0 mWλc Center Wavelength CW, I th+20mA 1290 1310 1330 nmΔλSpectral Width CW, I th+20mA , RMS (σ) 1 3 nmt r, t f Rise And Fall Times I F=I th, I th+20mA, 10~ 90% 0.3 nsΔP f / P f Tracking Error APC, -40~+85 ºC - - ±1.0 dBI m PD Monitor Current CW, I th+20mA,V RD=1V 100 μAI D PD Dark Current V RD=5V 0.1 μAC t PD Capacitance V RD=5V, f=1MHz 10 15 pFABSOLUTE MAXIMUM RATINGS (T C=25 ºC)Symbol Parameter Ratings UnitP o Optical Output Power 4 mWV RL LD Reverse V oltage 2 VV RD PD Reverse V oltage 10 VI FD PD Forward Current 1.0 mAT opr Operating Temperature -40~+85 ºCT stg Storage Temperature -40~+85 ºC******************************************************************************************************************************************************* OPTOWA Y TECHNOLOGY INC. No.38, Kuang Fu S. Road, Hu Kou, Hsin Chu Industrial Park, Hsin Chu, Taiwan 303*******************************************************************************************************************************************************OPTOWA Y TECHNOLOGY INC. No .38, Kuang Fu S. Road, Hu Kou, Hsin Chu Industrial Park, Hsin Chu, Taiwan 303ORDER INFORMATIONPart No.: F L − 3 3 4 □ □。

Single Color φ5 Round Shape Type5305S SeriesSpatial Distribution ExampleCondition : Ta = 25℃Spectral DistributionRelative Intensity vs. WavelengthCondition : Ta = 25℃, I F = 20mAWavelength [nm]R e l a t i v e I n t e n s i t yForward Voltage vs. Forward CurrentCondition : Ta = 25℃Forward Voltage V F (V)F o r w a r d C u r r e n t I F (m A )Forward Current vs. Relative IntensityCondition : Ta = 25℃Forward Current I F (mA)R e l a t i v e I n t e n s i t yTechnical Data (EBG/BG)FSingle Color φ5 Round Shape Type5305S SeriesSpatial Distribution ExampleCondition : Ta = 25℃Spectral DistributionRelative Intensity vs. WavelengthCondition : Ta = 25℃, I F = 20mAWavelength [nm]R e l a t i v e I n t e n s i t yForward Voltage vs. Forward CurrentCondition : Ta = 25℃Forward Voltage V F (V)F o r w a r d C u r r e n t I F (m A )Forward Current vs. Relative IntensityCondition : Ta = 25℃Forward Current I F (mA)R e l a t i v e I n t e n s i t yTechnical Data (EPG/PG)FSingle Color φ5 Round Shape Type5305S SeriesSpatial Distribution ExampleCondition : Ta = 25℃Spectral DistributionRelative Intensity vs. WavelengthCondition : Ta = 25℃, I F = 20mAWavelength [nm]R e l a t i v e I n t e n s i t yForward Voltage vs. Forward CurrentCondition : Ta = 25℃Forward Voltage V F (V)F o r w a r d C u r r e n t I F (m A )Forward Current vs. Relative IntensityCondition : Ta = 25℃Forward Current I F (mA)R e l a t i v e I n t e n s i t yTechnical Data (EPY/PY)FSingle Color φ5 Round Shape Type5305S SeriesSpatial Distribution ExampleCondition : Ta = 25℃Spectral DistributionRelative Intensity vs. WavelengthCondition : Ta = 25℃, I F = 20mAWavelength [nm]R e l a t i v e I n t e n s i t yForward Voltage vs. Forward CurrentCondition : Ta = 25℃Forward Voltage V F (V)F o r w a r d C u r r e n t I F (m A )Forward Current vs. Relative IntensityCondition : Ta = 25℃Forward Current I F (mA)R e l a t i v e I n t e n s i t yTechnical Data (EAY/AY)FSingle Color φ5 Round Shape TypeSpatial Distribution ExampleCondition : Ta = 25℃Spectral DistributionRelative Intensity vs. WavelengthCondition : Ta = 25℃, I F = 20mAWavelength [nm]R e l a t i v e I n t e n s i t yForward Voltage vs. Forward CurrentCondition : Ta = 25℃Forward Voltage V F (V)F o r w a r d C u r r e n t I F (m A )Forward Current vs. Relative IntensityCondition : Ta = 25℃Forward Current I F (mA)R e l a t i v e I n t e n s i t yTechnical Data (EAA/AA)5305S SeriesFSingle Color φ5 Round Shape Type5305S SeriesSpatial Distribution ExampleCondition : Ta = 25℃Spectral DistributionRelative Intensity vs. WavelengthCondition : Ta = 25℃, I F = 20mAWavelength [nm]R e l a t i v e I n t e n s i t yForward Voltage vs. Forward CurrentCondition : Ta = 25℃Forward Voltage V F (V)F o r w a r d C u r r e n t I F (m A )Forward Current vs. Relative IntensityCondition : Ta = 25℃Forward Current I F (mA)R e l a t i v e I n t e n s i t yTechnical Data (EVR/VR)FCondition : Ta = 25℃Wavelength[nm]Forward Current vs. Relative IntensityFCondition : Ta = 25℃Wavelength[nm]Forward Current vs. Relative IntensityF。

编织机安全操作的说明手册类型计算机类型部件类型CMS 933 769 OKC 000 - 001CMS 922 770 OKC 000 - 001CMS 830 C k&w 573 OKC 000 - 001CMS 822 574 OKC 000 - 001CMS 740 572 OKC 000 - 001CMS 730 T k&w 586 OKC 000 - 001CMS 730 S k&w 554 OKC 000 - 001CMS 711 571 OKC 000 - 001CMS 530 T 585 OKC 000 - 001CMS 530 566 OKC 000 - 001CMS 520 C 570 OKC 000 - 001CMS 520 567 OKC 000 - 001CMS 420 E multi gauge 577 OKC 000 - 001CMS 420 E 575 OKC 000 - 001标识号:242 409 CN日期: 14.12.2006版本号: 1.3H. Stoll GmbH & Co. KG, Stollweg 1, D-72760 Reutlingen, Germany 我们的产品正不断朝更高目标发展.因此它们便于进行技术修改.内容1安全指示 1-11.1正确使用................................................................................................................................1-11.2管理措施................................................................................................................................1-21.3员工条件和选择.....................................................................................................................1-31.3.1人员要求...................................................................................................................1-31.3.2人员选择...................................................................................................................1-41.4警告.......................................................................................................................................1-51.4.1使用的警告...............................................................................................................1-51.4.2图形字符的解释(ISO)...............................................................................................1-71.4.3文件中的警告...........................................................................................................1-81.5安全总说明............................................................................................................................1-91.5.1机械部分的隐患........................................................................................................1-91.5.2电流危害...................................................................................................................1-91.5.3操作材料带来的伤害...............................................................................................1-101.5.4其它危险.................................................................................................................1-101.6对于单独操作相位的安全须知.............................................................................................1-111.6.1运输安全须知.........................................................................................................1-111.6.2润滑操作安全须知..................................................................................................1-111.6.3电路连接的安全指令...............................................................................................1-121.6.4交换数据的安全指令...............................................................................................1-121.6.5生产安全预防措施..................................................................................................1-121.6.6打开的盖板的辅助安全说明....................................................................................1-131.6.7润滑,清洁和保养的安全须知...................................................................................1-141.6.8拆卸操作安全须知(拆卸).........................................................................................1-14 2机器的电气数据 2-12.1尺寸和重量............................................................................................................................2-12.2电气数据................................................................................................................................2-22.3针距范围................................................................................................................................2-32.4操作条件................................................................................................................................2-32.5储存条件................................................................................................................................2-42.6噪音.......................................................................................................................................2-4 3编织机的主要部件 3-13.1前面.......................................................................................................................................3-13.2侧面图(右边)..........................................................................................................................3-33.3后侧.......................................................................................................................................3-43.4视听信号元件.........................................................................................................................3-53.4.1指示灯......................................................................................................................3-53.4.2触摸屏......................................................................................................................3-63.4.3喇叭..........................................................................................................................3-73.4.4纱线控制装置上的灯.................................................................................................3-7 4组装和设置 4-14.1准备组装................................................................................................................................4-14.1.1准备安装地点............................................................................................................4-14.1.2准备好工具和辅助设备.............................................................................................4-14.1.3将编织机运送到安装地点.........................................................................................4-14.1.4拆卸编织机包装........................................................................................................4-14.2组装编织机............................................................................................................................4-24.2.1放上编织机...............................................................................................................4-24.2.2连接编织机...............................................................................................................4-54.2.3找正编织机.............................................................................................................4-104.3抬升导纱器和控制设备........................................................................................................4-124.3.1安装纱线控制装置..................................................................................................4-124.3.2安装指示灯.............................................................................................................4-144.4粘贴测量胶带.......................................................................................................................4-154.5接通编织机电源...................................................................................................................4-154.6如何立即停止机头运行........................................................................................................4-164.7检查安全设备.......................................................................................................................4-17安全指示 1正确使用 1.11-11 安全指示这些操作说明旨在让用户熟悉机器及其设计用途.说明手册介绍了有关如何安全,正确和有效使用此机器的重要信息.遵守这些说明有助于避免危险事故, 减少维修费用, 缩短停工时间以及提高此机器的可靠性和寿命.原文和图示无需与机器交货范围完全一致.本说明经过仔细翻译.如果对文字有任何疑问,请与所附原文件对照. 其它信息由以下途径提供:您所在国家的 STOLL 分公司或 STOLL 经销商Stoll 帮助热线:- 电话: +49-(0)7121-313-450- 传真: +49-(0)7121-313-455- 电子邮件:helpline@网址:Stoll 培训中心培训课程请保存本说明书以备将来之用.如果将来转售机器,请同时附上本操作说明.1.1 正确使用此机器的唯一用途在于生产线圈.只有适用于工业编织机的标准纱线才能在机器上进行生产.纱线帮助部分不适用于高强度的纱线或材质如 金属丝的安全生产. 如果有对机器的特别需求,请与Stoll 的任何代理处联系.说明书序1安全指示1.2 管理措施1-2 1.2 管理措施所有操作编织机的负责人都必须阅读过操作手册.操作员必须确认清楚明白了所有操作说明的内容并且能对机器操作负责人员进行讲解.除此以外操作员必须确保遵守所有本国/本地相关法律法规.例如规则.- 为了预防事故发生- 为了保护生命健康,- 为了保护环境,- 为了技术规则和- 为了一个安全合适的工作条件.编织机只能用于技术安全的条件和规定的条件下,明确所有的安全和隐患严格遵守操作说明.机器上的警告必须保持完整,清晰可辨.零部件获取参见零部件手册不能进行可能危及安全的修改,添加或转换.在维修和保管期间只能使用原产的Stoll零部件.在电脑,机器软件和控制系统/控制部件的操作系统中的程序上不能进行任意改动.机器上不能安装其他国家软件.安全指示 1员工条件和选择 1.31-31.3 员工条件和选择有关此机器的任何操作和作业都必须由可靠的人员执行. 遵照本国特定的相关法律法规. 1.3.1人员要求 为确保编织机可以正确而安全地运作,必须由专人进行严格合理的安装和操作. 电工 技工 编织专家 经过培训的或有基本技能的人员 电工必须是专人(电路方面的专家),可以正确执行分配的电路工作并能识别可能出现的危险. 专家必须有以下特点: 符合技术条件 掌握理论知识 有实际经验 熟悉相关(尤其是本国的)规定 熟悉操作系统 技师必须是专人(技术方面的专家),可以正确执行分配的电路工作并能识别可能出现的危险. 专家必须有以下特点: 符合技术条件 掌握理论知识 有实际经验 熟悉相关(尤其是本国的)规定 熟悉操作系统 编织专家必须是可以正确执行分配的电路工作并能识别可能出现的危险的专门人员.专家必须有以下特点:电工技工编织专家1安全指示1.3 员工条件和选择1-4符合编织机和花型设计系统的技术条件掌握理论知识有实际经验熟悉相关(尤其是本国的)规定熟悉操作系统经过培训或掌握基本知识的人员必须是基于以下特点且能在编织机上进行准确无误任务的人员:熟悉编织机的具体理论知识和实际的操作有实际经验熟悉可能出现的危险1.3.2 人员选择操作员必须确保机器上只认可一位人员进行同种工作.人员职责在下列工作项目中清楚地列出.表格显示每位人员的基本要求.工作项目人员安装技工电路连接电工启动编织专家编程编织专家设计编织专家,经过培训的或有基本技能的人员设置编织专家,经过培训的或有基本技能的人员操作编织专家,经过培训的或有基本技能的人员生产经过培训的或有基本技能的人员保养,维护,清洁编织专家,经过培训的或有基本技能的人员维护保养技工,电工或编织专家修理技工或电工拆卸工作技工或电工经过培训的或有基本技能的人员安全指示 1警告 1.41-51.4 警告本章中可以发现机器和文献中警告信息的解释. 1.4.1使用的警告 机器上相对于标准ISO 3864-2 的警告说明. 有效范围:除了美国和加拿大的所有国家 每个ISO 3864-2 的警告包括以下部分:图片解释 一个或多个警告说明 一个或多个阻止警告(可选择的) 一个或多个命令(可选择的) Tab. 1-1 警告部分Fig. 1-1 用于标注机器上警告的地方用于标注机器上警告的地方1安全指示1.4 警告1-6警告信息必须永远保持完整可辨别状态标记的顺序号在备件目录中.号码警告解释1 后盖板上的警告2 摩擦导纱轮上的警告3 左右边控制箱盖板上的警告4 主开关前盖板上的警告5 右边控制箱基座控制板和后盖板上的警告6 织物牵拉装置上的警告7 盖板下的警告8 前后针床的中央润滑系统上的警告.对于双机头, 右机头右边也是一样.Tab. 1-2 警告信息列表机器警告信息列表安全指示 1 警告 1.41.4.2 图形字符的解释(ISO)机器图形字符类型图片 解释总的警告说明危险电压撞击和切断的危险避免被飞离的机件部分或润滑材料击中的危险 警告说明吸入的危险禁止移动后盖板禁止罩盖卸下禁止说明禁止手工输入请配戴安全镜.断开主电源连接安上吸入保护传动装置命令等到所有控制箱上的LED 都关闭Tab. 1-3 用于编织机上的图形字符1安全指示1.4 警告1.4.3 文件中的警告文件中的警告有以下说明:安全说明(显示安全隐患)信号字符(危险,警告,小心)文本包括:- 危险类型和来源- 可能出现的结果- 危险和禁用装置的保护措施示例:危险高压!触电可能会导致严重的人员伤亡.将主开关设为"0".确保机器不会被再次开启.信号字符解释危险可能导致死亡或严重伤害(无法挽回)的隐患.警告可能导致死亡或严重伤害(无法挽回).警告可能导致轻伤(无法挽回).可能导致资产损失.警告(没有安全说明)Tab. 1-4 信号字符的解释安全指示1安全总说明 1.51.5 安全总说明1.5.1 机械部分的隐患原因保护性措施由于旋转或移动部件造成的伤害或危险请勿接触机器的内部区域.总是在中止期间停止机器在上升时关闭机器并确保其不会再次被开启.请配戴安全镜.损坏处机头和织针撞击时断裂的织针可能会导致伤害发生.请配戴安全镜.马达烫伤危险;针床和电器控制装置会很烫.戴保护性手套.受伤危险在通过压力张力弹簧进行上升动作时(例如操纵杆的主牵拉上,可能会积蓄一定的弹力. 在卸下前松开弹簧. 运行保护性装置.1.5.2 电流危害.原因保护性措施在机器的电器部件上进行操作时会有电击的危险. 只能由电工进行操作.关闭机器卸下建筑保险丝.确保机器不会被再次开启.连接器/插头松动或失效或电线损伤造成的电路故障会造成危及生命的电击.马上关闭机器.卸下建筑保险丝.确保机器不会被再次开启. 打消所有由电工造成的故障.1安全指示1.5 安全总说明1.5.3 操作材料带来的伤害.原因保护性措施化学物品在接触油脂,和其他化学物质时引起的危险. 佩戴保护性措施(例如护目镜,手套). 遵照本国特定的相关法律法规.注意操作者的安全须知.中央润滑系统管道破裂时高压油(高达30压力巴)造成的伤害. 马上关闭机器.确保机器不会被再次开启. 由电工替换损坏的线路. 马上擦去泄漏的油.中央润滑系统管道破裂时高压油(高达30压力巴)造成的伤害. 马上关闭机器.确保机器不会被再次开启. 由电工替换损坏的线路.如果油脂或其他物质被堵住或出现泄漏会有滑倒的危险. 马上擦除这些物质.遵照本国特定的相关法律法规.如果替换部件或用品没有进行专业处理则会导致环境污染. 确保以安全方式处理所有耗材和更换部件, 并尽量降低对环境的影响!遵照本国特定的相关法律法规.注意操作者的安全须知.1.5.4 其它危险原因保护性措施软麻布,灰尘和其他杂物导致失火或爆炸的危险.用金属或导电物质编织时由于金属尘屑堆积而造成短路的危险. 根据积灰程度清除整台机器上的软麻布,灰尘和其他杂物;至少每个班次一次.注意任何附加消耗.安上吸入保护传动装置..通过使用不适当的清洁材料造成的损害. 只能使用操作手册中提及的清洁材料如酒精等.不要使用对健康不利或自然界中酸性/腐蚀性的清洁材料.安全指示1对于单独操作相位的安全须知 1.61.6 对于单独操作相位的安全须知避免使用任何可能危害安全的操作模式!采取必要的安全预防措施确保机器只有处于安全可靠的状态时才能运转!只有在所有保护设备和安全措施都有效的情况下才能操作机器.特别是影响机器安全性的故障, 应立即进行维修或委托他人进行维修!必须遵守机器上和说明中的警告.这样可以保护自己和他人免受伤害也避免了极其和其他固定资产的损害.确保机器内无人.否则会有生命危险!遵照启动和关闭流程和指令.启动机器或设置运转中的机器之前, 请确保无人处在危险区域!1.6.1 运输安全须知风险类型措施重载造成的损害同时遵守本国载重运输的工业事故相关预防法规.在用地面运输工具运输时必须遵守本国特定的法律法规.1.6.2 润滑操作安全须知风险类型措施重载造成的损害遵照机器所有的机械数据.同时遵守本国载重运输的工业事故相关预防法规.否则会发生机器损坏事故. 卸下所有的运输固定部分.连接侧防护遮蔽罩 (在机器的左右两侧) 环境污染环保地去除保护胶片.遵照本国特定的相关法律法规.1安全指示1.6 对于单独操作相位的安全须知1.6.3 电路连接的安全指令风险类型措施在机器电器元件上操作时的生命危险. 由电工来进行机器的电路连接.注意机械数据.1.6.4 交换数据的安全指令风险类型措施电脑病毒!丢失数据或生产量.电脑病毒会通过USB端口或网络的未扫描的数据溜进机器. 将只有病毒的自由数据带入编织机.电脑病毒的风险数年内一直在增加.检查目标，确保连接到针织机的网络电脑和用于针织机的数据载体都不被电脑病毒感染！请特别注意,对于此种应用造成的任何损失 Fa. H. Stoll GmbH & Co.KG将不承担责任.如有更多问题,请联系Stoll-在线帮助.1.6.5 生产安全预防措施风险类型措施受伤危险闭合覆盖板.重新装上机器后挡板.闭合覆盖板.避开直视侧面松动的张力器.工具,纱线轴等物体要从机器内部卸下.如果机器正在运转,任何情况下都不得接触机器的内部区域.如果需要中止就停止机器.撞击时绕圈和吸尘装置危险. 不要接触织物牵拉滚轮.在机器操作时不要接触摩擦轮且拿开松散的衣物和线束.停止机器后还须等待喂纱轮停止运转.安全指示1对于单独操作相位的安全须知 1.6 风险类型措施纤维,灰尘和烟雾造成的健康危害. 在用对健康不利或容易损伤机器的纱线编织时要特别注意.纤维较重的纱线易危害健康的干燥物质玻璃纤维做成的纱线,退火金属纤维,石棉,碳纤维, PU或类似材料作的纤维采用合适方式避免由纤维,灰尘和烟雾造成的损失.遵照本国特定的相关法律法规.注意操作者的安全须知.更多问题请联系STOLL.编织金属或导电纱线时由于纤维和灰尘导致的故障(短路)隐患. 根据积灰程度清除整台机器上的软麻布,灰尘和其他杂物;至少每个班次一次.注意附加抽取.1.6.6 打开的盖板的辅助安全说明如果盖板打开操纵杆不能被固定到最高位置(生产).用户必须在这个位置握住操纵杆这样机器会在程序设定的速度下工作(类似与火车上的离合开关).风险类型措施被机头,横移,针床,和切夹纱装置撞击及折断的危险. 请勿接触机器的内部区域.逐步或缓慢地移动机头(见操作手册).三角和织针碎裂造成的伤害隐患. 请配戴安全镜.织物牵拉,辅助牵拉,牵拉梳和辅助针床撞击和吸入造成的伤害. 不要探入针床之间的缝隙中.确保双手,脸部,松开的衣服和其他松动的物品远离这些地方:小心轧伤.请勿接触织物牵拉辊和牵拉梳之间的区域:1安全指示1.6 对于单独操作相位的安全须知1.6.7 润滑,清洁和保养的安全须知风险类型措施被机头,横移,针床,和切夹纱装置撞击及折断的危险. 关闭编织机主开关.确保机器不会被再次开启.在机器后部操作完成后,重新安装上后盖板.健康隐患使用润滑油和润滑脂时,请注意适用各润滑产品的安全规则(安全数据表) !注意操作者的安全须知.环境污染确保以环保方式正确处理润滑油和润滑脂!遵照本国特定的相关法律法规.注意操作者的安全须知.1.6.8 拆卸操作安全须知(拆卸)长时间储存或抽气后的拆卸:风险类型措施电击的致命危险在机器电器元件上操作期间.电工将机器从主电源上断开.否则运输过程中会发生机器损坏事故. 遵照机器所有的机械数据.同时遵守本国载重运输的工业事故相关预防法规.拆卸和废料:风险类型措施在机器电器元件上操作期间. 电工将机器从主电源上断开.废旧处理中产生的环境污染遵照本国特定的相关法律法规.机器的电气数据2尺寸和重量 2.12 机器的电气数据2.1 尺寸和重量Fig. 2-1 编织机尺寸 (单位为 cm)A 宽度B 深度C 高度D 固定螺丝间距E 标称工作宽度机头的前后移动会导致上述动力载重作用在固定螺丝上.A B C D E 重量 (kg) 动态重量 (kg)933 510 106 205 270 244 2060 700CMS922 456 106 205 270 244 1960 660CMSCMS 830 C k&w 403 91 205 239 213 1690 740 822 403 91 205 239 213 1670 730CMS740 355 91 205 209 183 1530 620CMSCMS 730 T k&w 355 91 205 209 183 1510 630CMS 730 S k&w 355 91 205 209 183 1520 630 711 355 91 205 209 183 1440 600CMSCMS 530 T 270 91 205 153 127 1260 550CMS530 270 91 205 153 127 1240 540CMS 520 C 270 91 205 153 127 1250 540 520 270 91 205 153 127 1220 510CMSCMS 420 E 270 91 205 153 114 1170 500Tab. 2-1 尺寸,重量和动态重量2机器的电气数据2.2 电气数据2.2 电气数据电气数据值到 440 V ±10 %电压 20050 或 60 Hz相数 3按顺时针方向观察相位顺序额定电流8 A保险丝慢慢烧断主保险丝 (客户) 16每个相位功耗大约 2,6 kWTab. 2-2 编织机接线数据在连接机器前, 检查连接现场的主电压.通常不允许将其他制造商的电气或电子部件连接到此机器的内部电路.如果使用了这些部件, 我们不能保证机器的最佳运行性能.如果编织机由发电机供电, 需确保发电机提供的电压满足 EN 60204-1,Para. 的要求.4.3.1.如有问题, 请致电 STOLL 帮助热线.机器的电气数据2针距范围 2.32.3 针距范围针号机号额定宽度:50 in (127 cm) 额定宽度:72 in (183 cm)额定宽度:84 in (213 cm)E 3 149E 3.5 174E 4 199E 5 (E 2,5.2) 249 359 419E 7 (E 3.5.2) 349 503 587E 8 399 575 671E 10 (E 5.2) 499 719 839E 12 (E 6.2) 599 863 1007E 14 (E 7.2) 699 1007 1175E 16 (E 8.2) 799 1151 1343E 18, E9.2 899 1295Tab. 2-3 每个针床的针数可以将机器针距进行调整.欢迎订货.2.4 操作条件将机器放在厂房内水平,坚固的表面上不要将机器放在易燃易爆区域或地下室内环境温度 59 °F 到 113 °F/+15 °C 到 +45 °C相关湿度:- 最小 50 %- 最大 80%- 没有浓缩的但在导入纱线后如果相对湿度低于 50 %, 纺纱时可能会产生静电.在操作条件不符时请联系STOLL 帮助热线.2机器的电气数据2.5 储存条件2.5 储存条件如果编织机要存放较长时间则必须采取以下措施:1. 彻底清洁编织机.2. 润滑编织机.3. 当编织机被运到其他地方时,必须开启运输固定装置.4. 所有裸露的金属部分必须喷洒防腐材料.(例如 WD-40).5. 覆盖区域导纱器杆- 针床用充气纸/抗锈纸包裹.6. 用保护箔覆盖编织机.7. 将编织机存放在厂房中干燥处.储存温度 -15 °C 到 +60 °C.细心保存机器防止腐蚀尤其是海上空气腐蚀.2.6 噪音我们已在 CMS 340 TC E8 上分别对 CMS 3xx TC系列纺织机进行了检测.在可比条件下, CMS 3xx TC系列纺织机发出的声压级别低于指定值.所应用的标准:ISO/CD 9902 "编织机噪音规定"ISO/CD 9902-1 和 ISO/CD 9902-6.级别定义单位为dB(A) 平均声压级别 LpA 误差 KpA 平均声音输出级别LWA误差 KWACMS 340 TC 75,8 3,5 92 3,5Tab. 2-4 噪音编织机的主要部件3前面 3.1 3 编织机的主要部件3.1 前面Fig. 3-1 编织机正面视图号码名称号码名称1 信号灯(绿色,黄色) 9 操纵杆 (红色)2 纱线控制装置10 织物牵拉(主牵拉,辅助牵拉,牵拉梳)3 绕纱板(有纱轴) 11 织物收集室4 机头12 左控制箱5 保护盖(左,右) 13 织针和辅助针床(前面)6 保护盖(在机头和针床上) 14 触摸屏7 右控制箱15 USB-连接8 主开关(黄色)3编织机的主要部件3.1 前面内部视图Fig. 3-2 编织机内部视图号码名称号码名称1 机头 4 导纱器2 前针床 5 导纱器操纵杆3 左切夹纱针床编织机的主要部件3侧面图(右边) 3.2 3.2 侧面图(右边)Fig. 3-3 右边侧面图号码名称号码名称1 纱线控制设备 4 侧面纱线张力器2 导纱和控制设备 5 侧面保护盖3 摩擦喂纱轮3编织机的主要部件3.3 后侧3.3 后侧Fig. 3-4 后侧(没有后盖板部分)号码名称号码名称1 后针床 5 下垂电线(能源链)2 机头 6 变压器(保险丝)3 吸尘7 右侧控制装置4 左控制单元8 主驱动器编织机的主要部件 3 视听信号元件 3.43.4 视听信号元件编织机控制器连续不断地对纱线, 织物,机器的所有活动部分，马达和电子器件进行监控.如果出现故障机器将停止运转.信号发出黄色亮光，触摸屏上出现图形符号并且警报器停止.3.4.1 指示灯Fig. 3-5指示灯 (1)指示灯 (1) 指示编织机的运行状态.颜色编织机的状态绿色 编织机正在工作绿色 (慢速闪光) 用操纵杆使编织机停止运行绿色 (快速闪光) 编织机停止工作, 编织过程中有故障发生关主开关为关颜色编织机的状态绿色 编织机正在工作绿色 (闪光) 用操纵杆使编织机停止运行黄色 编织机停止工作, 编织过程中有故障发生 绿色，黄色在关机过程中两盏灯都亮着.时间大约为60秒 - 从关闭主开关直到机器完全被关闭.关 主开关为关Tab. 3-1 指示灯的颜色模型: 亮度信号灯(绿色)模型:双亮度信号灯(绿色，黄色)3 编织机的主要部件3.4 视听信号元件3.4.2 触摸屏最常见的故障原因在触摸屏上以图形符号显示.出现一个故障则出现一个图形符号(背景为黄色), 如果出现几个故障, 则相应的图形符号将依次显示出来.较少出现的故障 (如 硬盘故障) 则以一个普通的图形符号来显示.图形符号左保护盖右保护盖遮蔽罩盖左边纱线张力器右边纱线张力器纱线控制设备前面振动自停后面振动自停机头(动力检测器)前辅助针床后辅助针床振动自停(辅助针床)牵拉辅助牵拉辊牵拉梳左边摩擦喂纱轮右边摩擦喂纱轮加油编织机的主要部件3视听信号元件 3.4图形符号前针床横移后针床横移断电左边针床停止中央针床停止右边针床停止衣片计数器停机的各种原因Tab. 3-2 显示停机的图片3.4.3 喇叭信号声在以下情况中出现:如果机器由于错误而停止之后大约60秒主开关旋转到"0"信号音量可以打开或关闭 (标准设定 = 关闭).3.4.4 纱线控制装置上的灯Fig. 3-6 纱线控制装置上的灯为防止断纱或纱线用完,断纱控制装置/纱线控制张力臂会关闭编织机.故障显示在纱线控制设备上的LED上显示出来,信号灯闪黄光同时信息出现在触摸屏上.3编织机的主要部件3.4 视听信号元件准备组装 4.14 组装和设置4.1 准备组装4.1.1 准备安装地点安装地点编织机的安装地点必须满足以下条件:厂房内平坦, 坚实的地面编织机之间必须留出足够的空间, 以- 操作编织机- 从编织机中取出所编织的衣片不要将编织机安装在地下室4.1.2 准备好工具和辅助设备编织机在发送时将以下几种形式之一进行包装:在运输底板上, 用包装膜包装在运输底板上, 用包装箱包装在推车上所有包装类型都需要以下工具和辅助设备:编织机的备件箱- 编织机支脚垫片- 用于找正编织机的平头螺丝- 用于打开编织机后挡板的方口扳手六角螺丝起子可用于CMS 420 E.工具水平尺4.1.3 将编织机运送到安装地点将编织机连同包装运送到安装地点, 然后在安装地点拆去包装.4.1.4 拆卸编织机包装1. 当用包装箱运送时:拆去包装箱盖和侧板.2. 从织物收集存放室拆下备件箱.4.2 组装编织机4.2 组装编织机4.2.1 放上编织机用地面运输装置(如叉车)抬升编织机并进行运输.这样注意以下情况:重心位置显示在前部横杆上(左边运输位置中的机头).地面运输装置的两个抬升杆必须足够长这样可以抬升前后横杆.小心抬起并放置机器.如果撞到地板上会造成损坏.只能在机器底座或横杆上抬升机器.安装编织机1. 拆下将编织机固定在推车上的螺丝 1.2. 用叉车将编织机丛运输表面上抬起来.3. 将编织机放到安装地点4. 把备件箱中的垫片 (1) 放在编织机支脚下面.垫圈洞眼准确对准平头螺丝(2)Fig. 4-1 编织机支脚的垫片5. 将编织机放在地面上6. 移走木片, 包装带, 包装膜和包装纸.。