TSM-130-04-T-SV-M中文资料

集成电路英文代码及中文对照（一）我的文摘2009-11-21 11:32:53 阅读111 评论0 字号：大中小订阅产品名称型号规格性能说明LMLM24J 四运放(军用级)LM148J 通用四运放LM1875T 无线电控制/接收器LM224J 四运放(工业级)LM258N 分离式双电源双运放LM2901N 四电压比较器LM2904N 四运放LM301AN 通用运算放大器LM308N 单比较器LM311P 单比较器LM317L 可调三端稳压器/100mALM317T 可调三端稳压器/1.5ALM317K 可调三端稳压器/3ALM318 高速宽带运放LM324K 通用四运放LM331N V-F/F-V转换器LM336-2.5V 基准电压电路LM336 5V 基准电压电路LM337T 基准电压电路1ALM338K 可调三端稳压器5ALM339N 四比较器LM348N 四741运放LM358N 低功耗双运放LM361N 高速差动比较器LM386N 声频功率放大器LM3914N 十段点线显示驱动LM393N 低功耗低失调双比较器LM399H 精密基准源(6.9)LM723CN 可调正式负稳压器LM733CN 视频放大器LM741J 单运放LM741CN 双运放NENE521 高速双差分比较器NE5532 双运放NE5534 双运放NE555N 单运放NE555J 时基电路军品极NE556 双级型双时基电路NE564 锁相环NE565 锁相环NE567 音调译码器NE592 视频放大器OPOP07 低噪声运放OP27 超低噪声精密运放OP37 超低噪声精密运放光电耦合4N25 晶体管输出4N25MC 晶体管输出4N26 晶体管输出4N27 晶体管输出4N28 晶体管输出4N29 达林顿输出4N30 达林顿输出4N31 达林顿输出4N32 达林顿输出4N33 达林顿输出4N33MC 达林顿输出4N35 达林顿输出4N36 晶体管输出4N37 晶体管输出4N38 晶体管输出4N39 可控硅输出6N135 高速光耦晶体管输出6N136 高速光耦晶体管输出6N137 高速光耦晶体管输出6N138 达林顿输出6N139 达林顿输出MOC3020 可控硅驱动输出MOC3021 可控硅驱动输出MOC3023 可控硅驱动输出MOC3030 可控硅驱动输出MOC3040 过零触发可控硅输出MOC3041 过零触发可控硅输出MOC3061 过零触发可控硅输出MOC3081 过零触发可控硅输出TLP521-1 单光耦TLP521-2 双光耦TLP521-4 四光耦TLP621 四光耦TIL113 达林顿输出TIL117 TLL逻辑输出PC814 单光耦PC817 单光耦H11A2 晶体管输出H11D1 高压晶体管输出H11G2 电阻达林顿输出LF。

1FeaturesInputs/Outputs •Accepts differential or single-ended input •LVPECL, LVDS, CML, HCSL, LVCMOS •On-chip input termination resistors and biasing for AC coupled inputs•Six precision LVPECL outputs •Operating frequency up to 750 MHzPower •Options for 2.5 V or 3.3 V power supply •Core current consumption of 110 mA•On-chip Low Drop Out (LDO) Regulator for superior power supply rejectionPerformance •Ultra low additive jitter of 36 fs RMSApplications•General purpose clock distribution •Low jitter clock trees •Logic translation•Clock and data signal restoration•Wired communications: OTN, SONET/SDH, GE,10 GE, FC and 10G FC•PCI Express generation 1/2/3 clock distribution •Wireless communications•High performance microprocessor clock distributionApril 2014Figure 1 - Functional Block DiagramZL40205Precision 1:6 LVPECL Fanout Bufferwith On-Chip Input TerminationData SheetOrdering InformationZL40205LDG1 32 Pin QFN TraysZL40205LDF132 Pin QFNTape and ReelMatte TinPackage Size: 5 x 5 mm-40o C to +85o CTable of ContentsFeatures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Inputs/Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Change Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41.0 Package Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .52.0 Pin Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .63.0 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .73.1 Clock Inputs. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .73.2 Clock Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .123.3 Device Additive Jitter. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .153.4 Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .163.4.1 Sensitivity to power supply noise. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .163.4.2 Power supply filtering. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .163.4.3 PCB layout considerations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .164.0 AC and DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .175.0 Performance Characterization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .206.0 Typical Behavior . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .217.0 Package Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .238.0 Mechanical Drawing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24List of FiguresFigure 1 - Functional Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Figure 2 - Pin Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Figure 3 - Simplified Diagram of Input Stage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Figure 4 - Clock Input - LVPECL - DC Coupled. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Figure 5 - Clock Input - LVPECL - AC Coupled. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Figure 6 - Clock Input - LVDS - DC Coupled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Figure 7 - Clock Input - LVDS - AC Coupled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Figure 8 - Clock Input - CML- AC Coupled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Figure 9 - Clock Input - HCSL- AC Coupled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Figure 10 - Clock Input - AC-coupled Single-Ended . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Figure 11 - Clock Input - DC-coupled 3.3V CMOS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Figure 12 - Simplified Output Driver. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Figure 13 - LVPECL Basic Output Termination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Figure 14 - LVPECL Parallel Output Termination. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Figure 15 - LVPECL Parallel Thevenin-Equivalent Output Termination. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Figure 16 - LVPECL AC Output Termination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Figure 17 - LVPECL AC Output Termination for CML Inputs. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Figure 18 - Additive Jitter. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Figure 19 - Decoupling Connections for Power Pins. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Figure 20 - Differential and Single-Ended Output Voltages Parameter Definitions . . . . . . . . . . . . . . . . . . . . . . . . 18 Figure 21 - Input To Output Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19Change SummaryPage Item Change1Applications Added PCI Express clock distribution.6Pin Description Added exposed pad to Pin Description.8Figure 4 and Figure 5Removed 22 ohm series resistors from Figure 4 and 5. These resistor are not required; however there is no impact to performance if the resistors are included.16Power supply filtering 18Figure 20Clarification of V ID and V OD .Below are the changes from the February 2013 issue to the April 2014 issue:Page Item Change8Figure 4Changed text to indicate the circuit is not recommended for VDD_driver=2.5V.Below are the changes from the November 2012 issue to the February 2013 issue:Corrected typo of 0.3 Ohm to 0.15 Ohm.1.0 Package DescriptionThe device is packaged in a 32 pin QFNFigure 2 - Pin Connections2.0 Pin DescriptionPin # Name Description3, 6clk_p, clk_n,Differential Input (Analog Input). Differential (or single ended) input signals.For all input configurations see “Clock Inputs” on page 728, 27, 26, 25, 24, 23, 18, 17, 16, 15, 14, 13out0_p, out0_nout1_p, out1_nout2_p, out2_nout3_p, out3_nout4_p, out4_nout5_p, out5_nDifferential Output (Analog Output). Differential outputs.9, 19,22, 32vdd Positive Supply Voltage. 2.5 V DC or 3.3 V DC nominal.1, 8vdd_core Positive Supply Voltage. 2.5 V DC or 3.3 V DC nominal.2, 7,20, 21gnd Ground. 0 V.4vt On-Chip Input Termination Node (Analog). Center tap between internal 50 Ohmtermination resistors.The use of this pin is detailed in section 3.1, “Clock Inputs“, for various input signal types.5ctrl Digital Control for On-Chip Input Termination (Input). Selects differential input mode;0: DC coupled LVPECL or LVDS modes1: AC coupled differential modesThis pin are internally pulled down to GND. The use of this pin is detailed in section 3.1,“Clock Inputs“, for various input signal types.10, 11,12, 29,30, 31NC No Connection. Leave unconnected.Exposed Pad Device GND.3.0 Functional DescriptionThe ZL40205 is an LVPECL clock fan out buffer with six output clock drivers capable of operating at frequencies up to 750MHz.The ZL40205 provides an internal input termination network for DC and AC coupled inputs; optional input biasing for AC coupled inputs is also provided. The ZL40205 can accept DC or AC coupled LVPECL and LVDS input signals, AC coupled CML or HCSL input signals, and single ended signals. A pin compatible device with external termination is also available.The ZL40205 is designed to fan out low-jitter reference clocks for wired or optical communications applications while adding minimal jitter to the clock signal. An internal linear power supply regulator and bulk capacitors minimize additive jitter due to power supply noise. The device operates from 2.5V+/-5% or 3.3V+/-5% supply. Its operation is guaranteed over the industrial temperature range -40°C to +85°C.The device block diagram is shown in Figure 1; its operation is described in the following sections.3.1 Clock InputsThe device has a differential input equipped with two on-chip 50 Ohm termination resistors arranged in series with a center tap. The input can accept many differential and single-ended signals with AC or DC coupling as appropriate. A control pin is available to enable internal biasing for AC coupled inputs. A block diagram of the input stage is in Figure 3.Receiverclk_n 50clk_pVt 50BiasctrlFigure 3 - Simplified Diagram of Input StageThis following figures give the components values and configuration for the various circuits compatible with the input stage and the use of the Vt and ctrl pins in each case.In the following diagrams where the ctrl pin is logically one and the Vt pin is not connected, the Vt pin can be instead connected to VDD with a capacitor. A capacitor can also help in Figure 4 between Vt and VDD. This capacitor will minimize the noise at the point between the two internal termination resistors and improve the overall performance of the device.Figure 4 - Clock Input - LVPECL - DC CoupledFigure 5 - Clock Input - LVPECL - AC CoupledFigure 6 - Clock Input - LVDS - DC CoupledFigure 7 - Clock Input - LVDS - AC CoupledFigure 8 - Clock Input - CML- AC CoupledFigure 9 - Clock Input - HCSL- AC CoupledFigure 10 - Clock Input - AC-coupled Single-EndedFigure 11 - Clock Input - DC-coupled 3.3V CMOS3.2 Clock OutputsLVPECL has a very low output impedance and a differential signal swing between 1V and 1.6 V. A simplified diagram for the output stage is shown in Figure 12.The LVPECL to LVDS output termination is not shown since there is a different device with the same inputs and LVDS outputs.out_pout_nFigure 12 - Simplified Output DriverThe methods to terminate the ZL40205 LVPECL drivers are shown in the following figures.Figure 15 - LVPECL Parallel Thevenin-Equivalent Output TerminationFigure 16 - LVPECL AC Output TerminationFigure 17 - LVPECL AC Output Termination for CML Inputs3.3 Device Additive JitterThe ZL40205 clock fanout buffer is not intended to filter clock jitter. The jitter performance of this type of device is characterized by its additive jitter. Additive jitter is the jitter the device would add to a hypothetical jitter-free clock as it passes through the device. The additive jitter of the ZL40205 is random and as such it is not correlated to the jitter of the input clock signal.The square of the resultant random RMS jitter at the output of the ZL40205 is equal to the sum of the squares of the various random RMS jitter sources including: input clock jitter; additive jitter of the buffer; and additive random jitter due to power supply noise. There may be additional deterministic jitter sources, but they are not shown in Figure 18.Figure 18 - Additive Jitter3.4 Power SupplyThis device operates employing either a 2.5V supply or 3.3V supply.3.4.1 Sensitivity to power supply noisePower supply noise from sources such as switching power supplies and high-power digital components such as FPGAs can induce additive jitter on clock buffer outputs. The ZL40205 is equipped with a low drop out (LDO) regulator and on-chip bulk capacitors to minimize additive jitter due to power supply noise. The on-chip regulation, recommended power supply filtering, and good PCB layout all work together to minimize the additive jitter from power supply noise.3.4.2 Power supply filteringJitter levels may increase when noise is present on the power pins. For optimal jitter performance, the device should be isolated from the power planes connected to its power supply pins as shown in Figure 19. •10 µF capacitors should be size 0603 or size 0805 X5R or X7R ceramic, 6.3 V minimum rating •0.1 µF capacitors should be size 0402 X5R ceramic, 6.3 V minimum rating •Capacitors should be placed next to the connected device power pins •A 0.15 Ohm resistor is recommended3.4.3 PCB layout considerationsThe power nets in Figure 19 can be implemented either as a plane island or routed power topology without changing the overall jitter performance of the device.ZL402051891922320.1 µF 0.1 µFvdd_core10 µF 0.1 µF0.15 Ωvdd0.1 µF 10 µFFigure 19 - Decoupling Connections for Power PinsAbsolute Maximum Ratings*Parameter Sym.Min.Max.Units 1Supply voltage V DD_R-0.5 4.6V 2Voltage on any digital pin V PIN-0.5VDD V 4LVPECL output current I out30mA 5Soldering temperature T260 °C 6Storage temperature T ST-55125 °C 7Junction temperature T j125 °C 8Voltage on input pin V input VDD V 9Input capacitance each pin C p500fF 4.0 AC and DC Electrical Characteristics* Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied.* Voltages are with respect to ground (GND) unless otherwise statedRecommended Operating Conditions*Characteristics Sym.Min.Typ.Max.Units1Supply voltage 2.5 V mode V DD25 2.375 2.5 2.625V2Supply voltage 3.3 V mode V DD33 3.135 3.3 3.465V3Operating temperature T A-402585°C* Voltages are with respect to ground (GND) unless otherwise statedDC Electrical Characteristics - Current ConsumptionCharacteristics Sym.Min.Typ.Max.Units Notes 1Supply current LVPECL drivers -unloadedI dd_unload110mA Unloaded2Supply current LVPECL drivers - loaded (all outputs are active)I dd_load209mA Including powerto R L = 50DC Electrical Characteristics - Inputs and Outputs - for 3.3 V SupplyCharacteristics Sym.Min.Typ.Max.Units Notes1CMOS control logic high-level inputvoltageV CIH0.7*V DD V2CMOS control logic low-level inputvoltageV CIL0.3*V DD V3CMOS control logic Input leakagecurrentI IL1µA V I = V DD or 0 V4Differential input common modevoltageV CM 1.1 2.0V5Differential input voltage difference V ID0.251V6Differential input resistance V IR80100120ohm* This parameter was measured from 125 MHz to 750 MHz.* This parameter was measured from 125 MHz to 750 MHz.Figure 20 - Differential and Single-Ended Output Voltages Parameter Definitions7LVPECL output high voltage V OH V DD -1.40V 8LVPECL output low voltage V OL V DD - 1.62V 9LVPECL output differential voltage*V OD0.50.9VDC Electrical Characteristics - Inputs and Outputs - for 2.5 V SupplyCharacteristicsSym.Min.Typ.Max.Units Notes1Differential input common mode voltageV CM 1.1 1.6V 2Differential input voltage difference V ID 0.251V 3Differential input resistance V IR 80100120ohm 4LVPECL output high voltage V OH V DD -1.40V 5LVPECL output low voltage V OL V DD - 1.62V 6LVPECL output differential voltage*V OD0.40.9VDC Electrical Characteristics - Inputs and Outputs - for 3.3 V SupplyCharacteristicsSym.Min.Typ.Max.Units NotesAC Electrical Characteristics* - Inputs and Outputs (see Figure 21) - for 2.5/3.3 V supply.Characteristics Sym.Min.Typ.Max.Units Notes 1Maximum Operating Frequency1/t p750MHz2Input to output clock propagation delay t pd012ns3Output to output skew t out2out50100ps4Part to part output skew t part2part80300ps5Output clock Duty Cycle degradation t PWH/ t PWL-202Percent6LVPECL Output clock slew rate r SL0.75 1.2V/ns* Supply voltage and operating temperature are as per Recommended Operating ConditionsInputt Pt PWL t pdt PWHOutputFigure 21 - Input To Output TimingAdditive Jitter at 2.5 V*Output Frequency (MHz)Jitter MeasurementFilterTypical RMS (fs)Notes112512 kHz - 20 MHz 1392212.512 kHz - 20 MHz 1093311.0412 kHz - 20 MHz 85442512 kHz - 20 MHz 57550012 kHz - 20 MHz 506622.0812 kHz - 20 MHz 40775012 kHz - 20 MHz36Additive Jitter at 3.3 V*Output Frequency (MHz)Jitter MeasurementFilterTypical RMS (fs)Notes112512 kHz - 20 MHz 1152212.512 kHz - 20 MHz 853311.0412 kHz - 20 MHz 72442512 kHz - 20 MHz 55550012 kHz - 20 MHz 486622.0812 kHz - 20 MHz 41775012 kHz - 20 MHz395.0 Performance Characterization*The values in this table were taken with an approximate slew rate of 0.8 V/ns.*The values in this table were taken with an approximate slew rate of 0.8 V/ns.Additive Jitter from a Power Supply Tone*Carrier frequencyParameterTypicalUnitsNotes125MHz 25 mV at 100 kHz 115fs RMS 750MHz25 mV at 100 kHz59fs RMS* The values in this table are the additive periodic jitter caused by an interfering tone typically caused by a switching power supply. For this test, measurements were taken over the full temperature and voltage range for V DD = 2.5 V. The magnitude of the interfering tone is measured at the DUT.6.0 Typical BehaviorTypical Phase Noise at 622.08 MHzTypical Waveformat 155.52 MHzV OD versus FrequencyPropagation Delay versus TemperatureNote:This is for a single device. For more details see thePower Supply Tone Frequency (at 25 mV) versus PSRR at 125 MHz Power Supply Tone Frequency (at 25 mV) versus Additive Jitter at 125 MHzPower Supply Tone Magnitude (at 100 kHz) versus PSRR at 125 MHz Power Supply Tone Magnitude (at 100 kHz) versus Additive Jitter at 125 MHz7.0 Package CharacteristicsThermal DataParameter Symbol Test Condition Value UnitJunction to Ambient Thermal Resistance ΘJA Still Air1 m/s2 m/s 37.433.131.5o C/WJunction to Case Thermal Resistance ΘJC24.4o C/W Junction to Board Thermal Resistance ΘJB19.5o C/W Maximum Junction Temperature*T jmax125o C Maximum Ambient Temperature T A85o C© 2014 Microsemi Corporation. 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CN77000 R300和R500控制器,图片中含RHS-43孔锯, 易于钻圆孔。

有关订购信息, 请参见最后一页。

CN77333-A2 NEMA 12款方形开孔。

CN77533 NEMA 4方形开孔。

图片为实际尺寸。

1⁄16 DIN MICROMEGA ®自动调谐PID温度/过程控制器U 高精度：±0.5°C (0.9°F), 读数的0.03% U品质优秀, 还有5年保修支持 U 通用输入—过程电压/电流、热电偶、RTD U 双4位数字LED 显示屏和指示器, 用于显示输出和报警状态 U 可选RS232或RS485, OMEGA ® 协议U 继电器、SSR 、DC 脉冲、0 ~ 10 V, 以及 0 ~ 20 mA 输出类型 U 斜坡到设定值功能 U 通用电源, 90 ~ 250 Vac 或Vdc U 双输出和双报警功能U 隔离模拟输出或远程设定值可选将方形控制器放置于圆孔中！高精度、高品质MICROMEGA ®控制器在过程控制中提供无与伦比的灵活性。

每台设备均允许用户从10个热电偶类型（J 、K 、T 、E 、R 、S 、B 、C 、N 和JDIN ）、Pt RTD （100、500或1000 Ω, 385或392曲线）或者模拟电压或电流输入中选择输入类型。

 电压/电流输入可完全扩展到各工程单位，可选择小数点，是压力、流量或其他过程输入的理想之选。

MICROMEGA ®控制器具有大型双LED 显示屏，采用前面板配置，可选温度/过程输入，并接受90 ～ 250 Vac 或Vdc 通用电源。

提供单和双输入配置，CN77000系列适用于继电器、SSR 、DC 脉冲或模拟电压或电流输出。

单报警是标准配置。

可选项包括第二报警、 RS232、RS485、模拟输出以及远程设定值可选。

“300”系列控制器有许多特色，更大，紧凑型1⁄4 DIN 控制器，1⁄16 DIN 尺寸。

CompliantTSMIntegrated S tep -S ervoS tep -S ervo New集成式电机，一体化终端■ 智能型，内藏运动控制器■总线控制，多轴网络通讯■加强型电机，长寿命设计■高效率，高精度，高响应■ 低振动，低噪音，低发热步进伺服闭环步进StepperTSM平滑精确低发热/高效率TSMIntegrated S tep -S ervo特性基于高精度编码器的空间矢量电流控制算法，在全速度范围内均有优异的性能表现，即使在低速应用时仍可保持平稳、安静的运行。

------完美解决传统步进电机低速振动噪声问题利用高速响应的伺服控制技术升级强化了步进电机固有的刚性特质。

------在运行和静止时都确保定位的精确根据实际负载情况实时调整电流的大小，将发热降至最低。

静止时，电流几乎为零，无发热。

接近100%力矩输出能力，在最紧凑的空间内发挥出最大的能量转化 率，节能高效。

运动指令运动编程ID 1TSMIntegrated S tep -S ervo特性高速响应大力矩简单参数整定新增关键特性S/Q/C 型产品具备多达8路数字输入接口，4路数字输出接口及1路模拟量输入接口（仅TSM17/23/24/34产品） P 型产品具备内置编码器输出能力，并提供差分A+/A-，B+/B-及Z+/Z-信号输出（仅TSM17/23/24/34产品） 自动负载惯量识别功能现场总线型产品（RS-485，Modbus/RTU ，CANopen ）集成Daisy Chain 接口（仅TSM17/23/24/34产品） TSM34以太网通讯产品，集成Daisy Chain 接口 新增多种回原点模式 支持软件限位功能新增辅助电源输入功能，确保在主电源切断的情况下，保证控制电源不断，可查询编码器信息（仅TSM34产品）使用预定义的整定参数即可获得最优的性能表现及系统稳定性。

根据不同等级的控制要求，提供多种整定参数选择。

常用全系列‎场效应管‎M OS管型‎号参数封装‎资料‎场效应管分‎类型‎号‎简介‎‎封装DI‎S CRET‎EMOS‎FET ‎‎2N700‎0 6‎0V,0.‎115A ‎TO-9‎2DI‎S CRET‎EMOS‎FET ‎‎2N700‎2 6‎0V,0.‎2A ‎SOT-‎23D‎I SCRE‎T EMO‎S FET‎‎I RF51‎0A ‎100V,‎5.6A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎IRF5‎20A ‎100V‎,9.2A‎ TO‎-220‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎530A ‎ 10‎0V,14‎A T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F540A‎ 1‎00V,2‎8A ‎T O-22‎0DI‎S CRET‎EMOS‎FET ‎ I‎R F610‎A‎200V,‎3.3A ‎TO-2‎20D‎I SCRE‎T EMO‎S FET‎‎I RF62‎0A ‎200V‎,5A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎IRF6‎30A ‎ 200‎V,9A ‎ TO‎-220‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎634A ‎ 25‎0V,8.‎1A T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F640A‎ 2‎00V,1‎8A ‎T O-22‎0DI‎S CRET‎EMOS‎FET ‎ I‎R F644‎A‎250V,‎14A ‎TO-2‎20D‎I SCRE‎T EMO‎S FET‎‎I RF65‎0A ‎200V‎,28A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎IRF6‎54A ‎ 250‎V,21A‎ TO‎-220‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎720A ‎ 40‎0V,3.‎3A T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F730A‎ 4‎00V,5‎.5A ‎T O-22‎0 DI‎S CRET‎EMOS‎FET ‎ I‎R F740‎A‎400V,‎10A ‎TO-2‎20 D‎I SCRE‎T EMO‎S FET‎‎I RF75‎0A ‎400V‎,15A ‎ TO-‎220 ‎D ISCR‎E TEM‎O S FE‎T‎IRF8‎20A ‎ 500‎V,2.5‎A TO‎-220 ‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎830A ‎ 50‎0V,4.‎5A T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F840A‎ 5‎00V,8‎A‎T O-22‎0 DI‎S CRET‎EMOS‎FET ‎ I‎R F952‎0‎‎‎TO-2‎20D‎I SCRE‎T EMO‎S FET‎‎I RF95‎40 ‎‎‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎IRF9‎610 ‎‎‎ TO‎-220‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎9620 ‎‎‎ T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F P150‎A 1‎00V,4‎3A ‎T O-3P‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F P250‎A 2‎00V,3‎2A ‎T O-3P‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F P450‎A 5‎00V,1‎4A ‎T O-3P‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F R024‎A 6‎0V,15‎A‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F R120‎A 1‎00V,8‎.4A ‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F R214‎A 2‎50V,2‎.2A ‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F R220‎A 2‎00V,4‎.6A ‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F R224‎A 2‎50V,3‎.8A ‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F R310‎A 4‎00V,1‎.7A ‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F R902‎0TF ‎‎‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F S540‎A 1‎00V,1‎7A ‎T O-22‎0F D‎I SCRE‎T EMO‎S FET‎‎I RFS6‎30A ‎200V‎,6.5A‎ TO-‎220F ‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎S634A‎ 25‎0V,5.‎8A T‎O-220‎F DI‎S CRET‎EMOS‎FET ‎ I‎R FS64‎0A ‎200V,‎9.8A ‎TO-2‎20F ‎D ISCR‎E TEM‎O S FE‎T‎IRFS‎644A ‎ 250‎V,7.9‎A TO‎-220F‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F S730‎A 4‎00V,3‎.9A ‎T O-22‎0F D‎I SCRE‎T EMO‎S FET‎‎I RFS7‎40A ‎400V‎,5.7A‎ TO-‎220F ‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎S830A‎ 50‎0V,3.‎1A T‎O-220‎F DI‎S CRET‎EMOS‎FET ‎ I‎R FS84‎0A ‎500V,‎4.6A ‎TO-2‎20F ‎D ISCR‎E TEM‎O S FE‎T‎IRFS‎9Z34 ‎ -60‎V,12A‎ TO‎-220F‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F SZ24‎A 6‎0V,14‎A‎T O-22‎0FD‎I SCRE‎T EMO‎S FET‎‎I RFSZ‎34A ‎60V,‎20A ‎ TO-‎220F‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎U110A‎ 10‎0V,4.‎7A I‎-PAK‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎U120A‎ 10‎0V,8.‎4A I‎-PAK‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎U220A‎ 20‎0V,4.‎6A I‎-PAK‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎U230A‎ 20‎0V,7.‎5A I‎-PAK‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎U410A‎ 50‎0V ‎‎I-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F U420‎A 5‎00V,2‎.3A ‎I-PA‎KDI‎S CRET‎EMOS‎FET ‎ I‎R FZ20‎A‎‎‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎IRFZ‎24A ‎ 60‎V,17A‎ T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ IR‎F Z30 ‎‎‎‎TO-2‎20D‎I SCRE‎T EMO‎S FET‎‎I RFZ3‎4A ‎ 60V‎,30A ‎ TO‎-220‎DISC‎R ETE‎M OS F‎E T ‎ IRF‎Z40 ‎‎‎‎T O-22‎0DI‎S CRET‎EMOS‎FET ‎ I‎R FZ44‎A‎60V,‎50A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎IRLS‎530A ‎ 100‎V,10.‎7A,Lo‎g ic ‎T O-22‎0F D‎I SCRE‎T EMO‎S FET‎‎I RLSZ‎14A ‎60V,‎8A,Lo‎g ic ‎TO-2‎20F ‎D ISCR‎E TEM‎O S FE‎T‎IRLZ‎24A ‎ 60V‎,17A,‎L ogic‎ TO-‎220 ‎D ISCR‎E TEM‎O S FE‎T‎IRLZ‎44A ‎ 60V‎,50A,‎L ogic‎ TO-‎220 ‎D ISCR‎E TEM‎O S FE‎T‎SFP3‎6N03 ‎ 30V‎,36A ‎ TO‎-220‎DISC‎R ETE‎M OS F‎E T ‎ SFP‎65N06‎ 60‎V,65A‎ T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ SF‎P9540‎ -‎100V,‎17A ‎T O-22‎0DI‎S CRET‎EMOS‎FET ‎ S‎F P963‎4‎-250V‎,5A ‎TO-2‎20D‎I SCRE‎T EMO‎S FET‎‎S FP96‎44 ‎-250‎V,8.6‎A TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎SFP9‎Z34 ‎ -60‎V,18A‎ TO‎-220‎DISC‎R ETE‎M OS F‎E T ‎ SFR‎9214 ‎ -25‎0V,1.‎53A ‎D-PAK‎DIS‎C RETE‎MOS ‎F ET ‎ SF‎R9224‎ -2‎50V,2‎.5A ‎D-PA‎KDI‎S CRET‎EMOS‎FET ‎ S‎F R931‎0 -‎400V,‎1.5A ‎ D-P‎A KD‎I SCRE‎T EMO‎S FET‎‎S FS96‎30 ‎-200V‎,4.4A‎ TO‎-220F‎DIS‎C RETE‎MOS ‎F ET ‎ SF‎S9634‎ -2‎50V,3‎.4A ‎TO-2‎20F‎D ISCR‎E TEM‎O S FE‎T‎SFU9‎220 ‎-200‎V,3.1‎A I‎-PAK‎DISC‎R ETE‎M OS F‎E T ‎ SSD‎2002 ‎25V ‎N/P D‎u al ‎8SOP‎DIS‎C RETE‎MOS ‎F ET ‎ SS‎D2019‎ 20V‎P-ch‎Dual‎ 8SO‎P DI‎S CRET‎EMOS‎FET ‎ S‎S D210‎1 30‎V N-c‎h Sin‎g le ‎8SOP ‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎10N80‎A 80‎0V,10‎A T‎O-3P ‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎10N90‎A 90‎0V,10‎A T‎O-3P ‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎5N90A‎ 90‎0V,5A‎ T‎O-3P ‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎60N10‎‎‎ T‎O-3P‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎6N80A‎ 80‎0V,6A‎ T‎O-3P ‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎70N10‎A 10‎0V,70‎A T‎O-3P ‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎7N90A‎ 90‎0V,7A‎ T‎O-3P ‎DISC‎R ETE‎M OS F‎E T ‎ SSH‎9N80A‎ 80‎0V,9A‎ T‎O-3P ‎DISC‎R ETE‎M OS F‎E T ‎ SSP‎10N60‎A 60‎0V,9A‎ T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ SS‎P1N60‎A 6‎00V,1‎A‎T O-22‎0 DI‎S CRET‎EMOS‎FET ‎ S‎S P2N9‎0A ‎900V,‎2A ‎TO-2‎20 D‎I SCRE‎T EMO‎S FET‎‎S SP35‎N03 ‎30V,‎35A ‎ TO-‎220 ‎D ISCR‎E TEM‎O S FE‎T‎SSP3‎N90A ‎ 900‎V,3A ‎ TO‎-220 ‎DISC‎R ETE‎M OS F‎E T ‎ SSP‎4N60A‎ 60‎0V,4A‎ T‎O-220‎DIS‎C RETE‎MOS ‎F ET ‎ SS‎P4N60‎A S 6‎00V,4‎A‎T O-22‎0 DI‎S CRET‎EMOS‎FET ‎ S‎S P4N9‎0AS ‎900V,‎4.5A ‎ TO-‎220 ‎D ISCR‎E TEM‎O S FE‎T‎SSP5‎N90A ‎ 900‎V,5A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎SSP6‎0N06 ‎ 60V‎,60A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎SSP6‎N60A ‎ 600‎V,6A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎SSP7‎0N10A‎ 100‎V,55A‎ TO-‎220 ‎D ISCR‎E TEM‎O S FE‎T‎SSP7‎N60A ‎ 600‎V,7A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎SSP7‎N80A ‎ 800‎V,7A ‎ TO-‎220‎D ISCR‎E TEM‎O S FE‎T‎SSP8‎0N06A‎ 60V‎,80A ‎ TO-‎220 ‎D ISCR‎E TEM‎O S FE‎T‎SSR1‎N60A ‎ 600‎V,0.9‎A D-‎P AK ‎D ISCR‎E TEM‎O S FE‎T‎SSR2‎N60A ‎ 600‎V,1.8‎A D-‎P AK ‎D ISCR‎E TEM‎O S FE‎T‎SSR3‎055A ‎ 60V‎,8A ‎ D-‎P AK‎D ISCR‎E TEM‎O S FE‎T‎SSS1‎0N60A‎ 600‎V,5.1‎A TO‎-220F‎DIS‎C RETE‎MOS ‎F ET ‎ SS‎S2N60‎A 6‎00V,1‎.3A ‎T O-22‎0F D‎I SCRE‎T EMO‎S FET‎‎S SS3N‎80A ‎800V‎,2A ‎ TO-‎220F‎DISC‎R ETE‎M OS F‎E T ‎ SSS‎3N90A‎ 90‎0V,2A‎ TO‎-220F‎DIS‎C RETE‎MOS ‎F ET ‎ SS‎S4N60‎A 6‎00V,3‎.5A ‎T O-22‎0(F/P‎) DI‎S CRET‎EMOS‎FET ‎ S‎S S4N6‎0AS ‎600V,‎2.3A ‎TO-2‎20(F/‎P) D‎I SCRE‎T EMO‎S FET‎‎S SS4N‎60AS ‎600V‎,2.3A‎ TO-‎220F‎DISC‎R ETE‎M OS F‎E T ‎ SSS‎4N90A‎S 90‎0V,2.‎8A T‎O-220‎FDI‎S CRET‎EMOS‎FET ‎ S‎S S5N8‎0A ‎800V,‎3A ‎TO-2‎20F‎D ISCR‎E TEM‎O S FE‎T‎SSS6‎N60A ‎ 600‎V, ‎ TO‎-220(‎F/P)‎常用贴‎片三极管查‎询贴片‎三极管型号‎查询直插‎封装的型号‎贴片的型‎号901‎1 1T‎9012 ‎2T90‎13 J3‎9014‎J69‎015 M‎6901‎6 Y6‎9018 ‎J8S8‎050 J‎3YS8‎550 2‎T Y80‎50 Y1‎8550‎Y22‎S A101‎5 BA‎2SC18‎15 HF‎2SC9‎45 CR‎MMBT‎3904 ‎1AMM‎M BT39‎06 2A‎MMBT‎2222 ‎1PMM‎B T540‎1 2L‎M MBT5‎551 G‎1MMB‎T A42 ‎1DMM‎B TA92‎2DB‎C807-‎16 5A‎BC80‎7-25 ‎5BBC‎807-4‎0 5C‎B C817‎-16 6‎ABC8‎17-25‎6BB‎C817-‎40 6C‎BC84‎6A 1A‎BC84‎6B 1B‎BC84‎7A 1E‎BC84‎7B 1F‎BC84‎7C 1G‎BC84‎8A 1J‎BC84‎8B 1K‎BC84‎8C 1L‎BC85‎6A 3A‎BC85‎6B 3B‎BC85‎7A 3E‎BC85‎7B 3F‎BC85‎8A 3J‎BC85‎8B 3K‎BC85‎8C 3L‎2SA7‎33 CS‎UN21‎11 V1‎UN21‎12 V2‎UN21‎13 V3‎UN22‎11 V4‎UN22‎12 V5‎UN22‎13 V6‎2SC3‎356 R‎232S‎C3838‎AD2‎N7002‎702‎回答人的‎补充‎2010-‎02-01‎17:3‎1 Ste‎m pel ‎Typ‎Hers‎t.B‎a se‎G eh?u‎s eS‎t anda‎r d Ve‎r glei‎c hsty‎pJ‎0HS‎M S-28‎40H‎PC‎SOT2‎3sc‎h ottk‎y dio‎d e‎J01‎S O290‎6R‎N‎2N29‎06‎J03‎S O290‎7AR‎R‎2N2‎907A‎J05‎SO2‎907R‎R‎2N‎2907‎J1‎HSMS‎-2841‎HP‎KS‎O T23‎scho‎t tky ‎d iode‎J1‎ZC8‎30Z‎e tC‎Z‎C820 ‎v aric‎a ps ‎J1‎B SS13‎8LM‎o tM‎SOT‎23n‎-ch e‎n h TM‎O S fe‎t J‎12S‎O2906‎A R‎R‎2N29‎06A‎J1A‎ZC83‎0AZ‎e tC‎SOT‎23v‎a rica‎p hyp‎e rabr‎u pt 2‎8V 10‎p F@2V‎J1‎BZC‎830B‎Zet‎CS‎O T23‎vari‎c ap h‎y pera‎b rupt‎28V ‎10pF@‎2V ‎J2Z‎C833‎Zet‎CS‎O T23‎ZC82‎3J‎2AZ‎C833A‎Zet‎C‎S OT23‎var‎i cap ‎h yper‎a brup‎t 28V‎33pF‎@2V ‎J2B‎ZC83‎3BZ‎e tC‎SOT‎23v‎a rica‎p hyp‎e rabr‎u pt 2‎8V 33‎p F@2V‎J3‎ZC8‎31Z‎e tC‎SOT‎23Z‎C821‎J32‎SO5‎400R‎SGS‎R‎2N54‎00‎J33‎S O540‎1RS‎G SR‎2‎N5401‎J3‎9SO‎692R‎SGS‎‎p np V‎c e 30‎0V‎J3A‎Z C831‎AZe‎tC‎SOT2‎3va‎r icap‎hype‎r abru‎p t 28‎V 15p‎F@2V ‎J3B‎ZC8‎31B‎Z et‎CSO‎T23‎v aric‎a p hy‎p erab‎r upt ‎28V 1‎5pF@2‎V J‎3DM‎S B81T‎1Mo‎t‎vhf‎pnp ‎f T 0.‎6GHz‎J4‎ZC83‎2Ze‎tC‎SOT2‎3ZC‎823‎J4A‎MBV1‎09M‎o tC‎SOT‎232‎9pF V‎H F va‎r icap‎diod‎eJ‎4AZ‎C832A‎Zet‎C‎S OT23‎var‎i cap ‎h yper‎a brup‎t 28V‎22pF‎@2V ‎J4B‎ZC83‎2BZ‎e tC‎SOT‎23v‎a rica‎p hyp‎e rabr‎u pt 2‎8V 22‎p F@2V‎J5‎ZC8‎34Z‎e tC‎SOT‎23Z‎C824‎‎。

拉丝线SM 3000 L放线单元SM 3000 L 卧式放线机是为大直径高碳钢丝而设计。

它是由重型钢管及钢板焊接而成，装有弹动棒保持钢丝圈于其位置，当拉丝机将钢丝拉动是一圈一圈将钢丝放出。

这单元不需任何特别安装或基础，只需要用螺钉固定于地上，连续防线需要两个单元并列安装，每两单元的载线量为3000公斤。

钢丝盘条是从单元的前部装上，但吊钩是从单元后方推出，这样操作人员但装上盘条只需单向从单元的前往后，避免站于放线是的危险地区。

最大钢丝直径16.00 mm，单元可使用最细钢丝直径为5.50 mmMTS拉丝机描述MTS干式拉丝机的特点是简单、可靠、适用。

独到之处是冷却系统维修量低，有效地解决了钢丝弯曲和扭转问题，保证成品钢丝具良好的质量。

卷筒呈倾斜排列，采用感应同步调速，适用于大、中规格的钢丝拉拔，而MTX拉丝机适用于拉拔小规格的钢丝。

概要机身牢固，用钢板焊接而成，由单头或多头组成，再用螺栓连接，便于吊装，运输和安装。

每台拉丝机的重量和尺寸分别不超达12,000kg和10,000mm。

卷筒及模匣，马达，刹车，防护罩，进水管和排水管，压缩空气管等都装在机身上。

照明灯装在二卷筒之间机架上。

无需特殊的基础，用户有要求除外。

每台拉丝机内部电气接线都完成，到货即可安装。

选购件（供货不包括）：- 第一卷筒装有上放线- 最后一道采用双层卷筒，中间带矫直器- 乱线开关，热保护器- 钢丝出口装激光测径仪- “D.D.A.” 多台机器连机控制管理系统- 冷却水流量指示器- 旋转模- 搅拌模- 轧尖机/对焊机用电源插座- 仿生保护罩- 钢丝可从最后卷筒吊下的卷筒拉丝卷筒用C50锻钢制成，用中频硬化处理，表面硬度达到HRC62，耐磨性能良好。

拉丝卷筒上的钢丝受力部分用碳化钨热喷涂；涂陶瓷适用于拉低碳钢或不锈钢丝。

卷筒表面光洁的外形，防止钢丝上移时叠丝。

每个卷筒采用窄缝冷却，用有压力冷却水冷却卷的内壁。

采用了涡流冷却方法，该窄缝冷却又有进一步的提高，内筒采用特殊的不生锈材料制成。

1/12February 2005STP130NS04ZBSTB130NS04ZB - STW130NS04ZBN-CHANNEL CLAMPED - 7 m Ω - 80A TO-220/D²PAK/TO-247FULLY PROTECTED MESH OVERLAY™ MOSFETTable 1: General Featuress TYPICAL R DS (on) = 7 m Ωs 100% AVALANCHE TESTEDs LOW CAPACITANCE AND GATE CHARGE s175°C MAXIMUM JUNCTION TEMPERATUREDESCRIPTIONThis fully clamped MOSFET is produced by using the latest advanced Company’s Mesh Overlay process which is based on a novel strip layout.The inherent benefits of the new technology cou-pled with the extra clamping capabilities make this product particularly suitable for the harshest oper-ation conditions such as those encountered in the automotive environment .Any other application re-quiring extra ruggedness is also recommended.APPLICATIONSs HIGH SWITCHING CURRENT s LINEAR APPLICATIONSTable 2: Order CodesTYPE V DSS R DS(on)I D STP130NS04ZB STB130NS04ZB STW130NS04ZBCLAMPED CLAMPED CLAMPED< 9 m Ω< 9 m Ω< 9 m Ω80 A 80 A 80 ASales Type Marking Package Packaging STP130NS04ZB P130NS04ZB TO-220TUBE STB130NS04ZBT4B130NS04ZB D ²PAK TAPE & REELSTW130NS04ZBW130NS04ZBTO-247TUBERev. 2STP130NS04ZB - STB130NS04ZB - STW130NS04ZB2/12Table 3: Absolute Maximum ratings( ) Pulse width limited by safe operating areaTable 4: Thermal Data(*)When mounted on 1 inch ² FR4 2oZ CuTable 5: Avalanche CharacteristicsSymbol ParameterValue Unit V DS Drain-source Voltage (V GS = 0)CLAMPED V V DG Drain-gate Voltage CLAMPED V V GS Gate- source VoltageCLAMPEDV I D Drain Current (continuous) at T C = 25°C 80A I D Drain Current (continuous) at T C = 100°C 60A I DG Drain Gate Current (continuous)± 50mA I GS Gate Source Current (continuous)± 50mA I DM ( )Drain Current (pulsed)320A P TOT Total Dissipation at T C = 25°C 300W Derating Factor2.0W/°C V ESD(G-S)Gate-Source ESD(HBM-C=100 pF, R=1.5 K Ω)4KV T j T stgMax Operating Junction Temperature Storage Temperature-55 to 175°CTO-220D²PAK TO-247Unit Rthj-case Thermal Resistance Junction-case Max 0.50°C/W Rthj-pcb (*)Thermal Resistance Junction-pcb Max --35--°C/WRthj-a Thermal Resistance Junction-ambient Max 62.5--50T lMaximum Lead Temperature For Soldering Purpose (1.6 mm from case, for 10 sec)300°CSymbol ParameterMax ValueUnit I AR Avalanche Current, Repetitive or Not-Repetitive (pulse width limited by T j max)80A E ASSingle Pulse Avalanche Energy(starting T j = 25 °C, I D = I AR , V DD = 30 V)500mJ3/12STP130NS04ZB - STB130NS04ZB - STW130NS04ZBELECTRICAL CHARACTERISTICS (T CASE =25°C UNLESS OTHERWISE SPECIFIED)Table 6: On /OffTable 7: DynamicTable 8: Source Drain Diode(1) Pulsed: Pulse duration = 300 µs, duty cycle 1.5 %.(2) Pulse width limited by safe operating area.Symbol ParameterTest ConditionsMin.Typ.Max.Unit V (BR)DSS Clamped Voltage I D = 1 mA, V GS = 0-40 < Tj < 175 °C 33V I DSS Zero Gate VoltageDrain Current (V GS = 0)V DS = 16 V,Tj = 25 °C V DS = 16 V,Tj = 125 °C 10100µA µA I GSS Gate-body Leakage Current (V DS = 0)V GS = ±10 V,Tj = 25 °C 10µA V GSS Gate-SourceBreakdown Voltage I GS = ±100 µA 18V V GS(th)Gate Threshold Voltage V DS = V GS = I D = 1 mA 24V R DS(on)Static Drain-source On ResistanceV GS = 10 V ,I D = 40 A79m ΩSymbol ParameterTest ConditionsMin.Typ.Max.Unit g fs ForwardTransconductance V DS = 15 V, I D = 40 A50S C iss C oss C rss Input Capacitance Output Capacitance Reverse Transfer Capacitance V DS = 25 V, f = 1MHz, V GS = 027001275285pF pF pF t d(on)t f t d(off)t f Turn-on Delay Time Fall TimeTurn-off Delay Time Fall TimeV DD = 17.5 V, I D = 40 A,R G = 4.7 Ω, V GS = 10 V (see Figure 15)40220170100ns ns ns ns Q g Q gs Q gdTotal Gate Charge Gate-Source Charge Gate-Drain ChargeV DD = 20 V, I D = 80 A,V GS = 10 V (see Figure 17)802027105nC nC nCSymbol ParameterTest ConditionsMin.Typ.Max.Unit I SD I SDM (2)Source-drain CurrentSource-drain Current (pulsed)80320A A V SD (1)Forward On Voltage I SD = 80 A, V GS = 0 1.5V t rr Q rr I RRMReverse Recovery Time Reverse Recovery Charge Reverse Recovery CurrentI SD = 80 A, di/dt = 100A/µs V DD = 25V, T j = 150°C (see Figure 16)900.184ns µC ASTP130NS04ZB - STB130NS04ZB - STW130NS04ZB4/12Figure 3: Safe Operating AreaFigure 6: Thermal Impedance5/12STP130NS04ZB - STB130NS04ZB - STW130NS04ZBFigure 9: Gate Charge vs Gate-source VoltageFigure 12: Normalized On Resistance vs Tem-STP130NS04ZB - STB130NS04ZB - STW130NS04ZB6/12Figure 15: Switching Times Test Circuit For Resistive LoadFigure 16: Test Circuit For Diode Recovery Be-haviourFigure 17: Gate Charge Test CircuitSTP130NS04ZB - STB130NS04ZB - STW130NS04ZB7/12STP130NS04ZB - STB130NS04ZB - STW130NS04ZB8/12STP130NS04ZB - STB130NS04ZB - STW130NS04ZB9/12STP130NS04ZB - STB130NS04ZB - STW130NS04ZB10/12TAPE AND REEL SHIPMENT (suffix ”T4”)*TUBE SHIPMENT (no suffix)* D2PAK FOOTPRINT* on sales typeDIM.mm inchMIN.MAX.MIN.MAX.A33012.992B 1.50.059C12.813.20.5040.520D20.20795G24.426.40.960 1.039N100 3.937T30.4 1.197BASE QTY BULK QTY10001000REEL MECHANICAL DATA DIM.mm inchMIN.MAX.MIN.MAX.A010.510.70.4130.421B015.715.90.6180.626D 1.5 1.60.0590.063D1 1.59 1.610.0620.063E 1.65 1.850.0650.073F11.411.60.4490.456K0 4.8 5.00.1890.197P0 3.9 4.10.1530.161P111.912.10.4680.476P2 1.9 2.10.0750.082R50 1.574T0.250.350.00980.0137W23.724.30.9330.956TAPE MECHANICAL DATASTP130NS04ZB - STB130NS04ZB - STW130NS04ZB Table 9: Revision HistoryDate Revision Description of Changes 10-June-20041First Release.14-Jan-20052Inserted D²PAK, Complete version.11/12STP130NS04ZB - STB130NS04ZB - STW130NS04ZBInformation furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.The ST logo is a registered trademark of STMicroelectronicsAll other names are the property of their respective owners© 2005 STMicroelectronics - All Rights ReservedSTMicroelectronics group of companiesAustralia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan - Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States of America12/12。

xxTSM数据备份项目日常维护手册xxxxxx科技有限公司目录1前言 (3)2TSM巡检操作手册 (4)2.1查看TSM服务器 (4)2.2查看TSM MANAGE CONSOLE (4)2.3在TSM服务器上登录到管理界面 (5)2.4在TSM CLIENT端检查 (6)3TSM常见问题的处理 (6)3.1TSM S ERVER的故障处理 (6)3.1.1所有的备份和恢复操作都无法进行 (6)3.1.2如何获得TSM错误描述 (7)3.1.3系统出现无法读写磁带或磁盘的故障 (7)3.1.4处理带库故障后TSM工作不正常。

(8)3.1.5 a tape in library does not display in q libv (8)3.1.6reclaim process not run (8)3.1.7how to delete archive log files after backup (8)3.1.8windows device manager, found a drive mark as yellow (9)3.2TSM C LIENT的故障处理 (9)3.2.1TSM Client无法连接TSM Server (9)3.2.2TSM Client备份大文件时经常不成功 (9)3.2.3ANS1312E error in dsmerror.log (10)3.2.4when backup data, error: media can not mount (10)3.2.5ANR8779E Unable to open drive mt0.3.0.3, error number=170 (10)4日常维护 (10)4.1启动和停止TSM服务器 (10)4.2进入管理员界面 (11)4.3进入TSM CLIENT文件备份/恢复界面 (11)4.4管理数据库和日志 (11)4.5管理磁带库 (12)4.5.1查看带库中磁带驱动器状态： (12)4.5.2磁带的分配： (12)4.5.3检查活动日志，有可能要求作出回应， (12)4.5.4查看磁带上的备份内容： (13)4.5.5从磁带库中取出已使用的磁带放到异地保存： (13)4.5.6将取出的磁带重新放入磁带库中： (13)4.5.7向磁带库中增加新的供TSM使用的磁带： (13)4.5.8将新磁带添加到storage pool 中（可选） (13)4.5.9重复利用磁带库中的磁带 (13)4.6管理磁带库存储池 (14)4.7管理客户端节点 (14)4.7.1删除一个客户端节点 (14)4.7.2修改节点密码 (14)4.8定时备份维护 (14)4.8.1TSM Clien/TDP节点定时备份守候进程 (14)4.8.2客户端停止定时备份 (14)4.8.3查看定时备份日志 (15)4.9建立策略域(P OLICY D OMAIN) (15)4.10监控TSM S ERVER运行情况 (15)5IBM客户支持服务流程 (16)1前言本文档是TSM巡检操作手册，常见问题的处理和日常维护。

TSM规格资料规格客户名称5514G-2PPTJ530S5514G-3A PPJ717QS5515G-1BV POMM9045XAP5516G-1PA6CM10175514G-3B PPTJ911S5608G-5L/5PPLA880C5515G-1V POMM9045XAP5514G-3/3A PPJ717QS5527G-1PBT1401X065608G-1PPX660C5601G-3B PPDA504C5608G-7PPX675CS5601G-4C PP90705515G-1AL POMM25-455608G-5LS PPLA880C5515G-1AL POMM9045XAP5516G-1P-PA6-N-0065516G-1B P-POMMC-N-0045514G-2PPCN2015/PPTJ530S5512G-2C ABS450YMH55513G-1PC5603G-5A PA6MT409AHSTSM5512G-2C东丽 ABS 450YMH55603G-2A PA6680G14AHS5515G-1BV宝理 POM M9045LV5513G-1L PC L-1225Z5527G-1东丽 PBT1401X065526G-1PC+ABS PAX-1439CN5512G-2B ABS-606R-1TSM5514G-2N PPTJ530S中山中山日本日本中山三井日本中山三井三井三井三井三井三井三井东丽东丽国产三井东丽日本三井国产宝理东丽三井三井三井宝理杜邦TSM规格资料规格客户名称5514G-2PPTJ530S5514G-3A PPJ717QS5515G-1BV POMM9045XAP5516G-1PA6CM10175514G-3B PPTJ911S5608G-5L PPLA880C5515G-1V POMM9045XAP5514G-3/3A PPJ717QS5527G-1PBT1401X065608G-1PPX660C5601G-3B PPDA504C5608G-7PPX675CS5601G-4C PP90705515G-1AL POMM25-455608G-5LS PPLA880C5515G-1AL POMM9045XAP5516G-1P-PA6-N-0065516G-1B P-POMMC-N-0045514G-2PPCN2015TSM5608G-6TSOP-GP6BCSTSM5608G-6B TSOP-GP6BCSTSM5608G-7X675CSTSM5608G-5LA880CTSM5608G-5L LA880CTSM5608G-1X660CTSM5608G-5W LA880CWTSM5512G-2B450YMH5TSM5512G-2A700-314TSM5518G-2HHM5502TSM5514G-2TJ530STSM5603G-2B CM3001G30TSM5601G-4C9070BKSTSM5518G-3茂名石化 5502TSM5523G-2(AES)未知TSM5515G-1A M25-44TSM5603G-1B CM1011G30TSM5601G-3B DA504CTSM5514G-3B TJ911S/J966HPCTSM5514G-3A J717QSTSM5746G-4未知TSM5515G-1B M90-44TSM5515G-2APOM100T BK602TSM5601G-9BLPPTA899CPPTA899CTSM5601G-9B东丽TSM5512G-2AL ABS 700-314NATTSM5514G-3AL PPJ717QSTSM5514G-3BL PPTJ911S 或 J966HPC 大科能TSM5526G-2PC+ABS MPC6801上海石化TSM5518G-3HDPE-SH850大科能TSM5523G-2AES -W211TSM5608G-6TSOP-GP6BCS三井TSM5608G-6B TSOP-GP6BCS三井TSM5608G-7X675CS三井TSM5608G-5LA880C三井TSM5608G-5L LA880C三井TSM5608G-1X660C三井TSM5608G-5W LA880CW三井TSM5512G-2B450YMH5东丽TSM5512G-2A700-314东丽TSM5518G-2HHM5502国产TSM5514G-2TJ530S三井TSM5603G-2B CM3001G30东丽TSM5601G-4C TPO9070BKS日本三井TSM5518G-3茂名石化 5502国产TSM5523G-2(AES)未知TSM5515G-1A M25-44宝理TSM5603G-1B CM1011G30东丽TSM5601G-3B DA504C三井TSM5514G-3B TJ911S/J966HPC三井TSM5514G-3A J717QS三井TSM5746G-4未知TSM5515G-1B M90-44宝理TSM5514G-2LS和TSM5514G-2L对应资料都是 TJ530S。

BEFORE USE ....Thank you for choosing M-System. Before use, please check contents of the package you received as outlined below.If you have any problems or questions with the product, please contact M-System’s Sales Office or representatives.■PACKAGE INCLUDES:Signal conditioner(body + base socket + input resistor) (1)Input resistor is provided only with current input type.■MODEL NO.Confirm M odel No. marking on the product to be exactly what you ordered.■INSTRUCTION MANUALThis manual describes necessary points of caution when you use this product, including installation, connection and basic maintenance procedures.POINTS OF CAUTION■CONFORMITY WITH EU DIRECTIVES• This equipment is suitable for Pollution Degree 2 and In-stallation Category II (transient voltage 2500V). Rein-forced insulation (signal input or output to power input: 300V) and basic insulation (signal input to output: 300V) are maintained. Prior to installation, check that the insu-lation class of this unit satisfies the system requirements.• Altitude up to 2000 meters.• The equipment must be mounted inside a panel.• The equipment must be installed such that appropriate clearance and creepage distances are maintained to con-form to CE requirements. Failure to observe these re-quirements may invalidate the CE conformance.• The actual installation environments such as panel con-figurations, connected devices, connected wires, may af-fect the protection level of this unit when it is integrated in a panel system. The user may have to review the CE requirements in regard to the whole system and employ additional protective measures* to ensure the CE con-formity.* For example, installation of noise filters and clamp fil-ters for the power source, input and output connected to the unit, etc.• Install lightning surge protectors for those wires connect-ed to remote locations.■POWER INPUT RATING & OPERATIONAL RANGE• Locate the power input rating marked on the product and confirm its operational range as indicated below:100 – 240V AC rating: 85 – 264V, 47 – 66 Hz,approx. 5VA at 100V ACapprox. 6VA at 200V ACapprox. 7VA at 264V AC 24V DC rating: 24V ±10%, approx. 3W■GENERAL PRECAUTIONS• Before you remove the unit from its base socket or mount it, turn off the power supply and input signal for safety.■ENVIRONMENT• Indoor use.• When heavy dust or metal particles are present in the air, install the unit inside proper housing with sufficient ventilation.• Do not install the unit where it is subjected to continuous vibration. Do not subject the unit to physical impact.• Environmental temperature must be within -5 to +60°C (23 to 140°F) with relative humidity within 30 to 90% RH in order to ensure adequate life span and operation.■WIRING• Do not install cables close to noise sources (relay drive cable, high frequency line, etc.).• Do not bind these cables together with those in which noises are present. Do not install them in the same duct.■AND ....• The unit is designed to function as soon as power is sup-plied, however, a warm up for 20 minutes is required for satisfying complete performance described in the data sheet.• With current output, when load resistance is less than the value described in the data sheet, it may shorten ap-propriate life duration.COMPONENT IDENTIFICATION■HOW TO OPEN THE FRONT COVER:Position your finger on the hook at the top of the front cover and pull.■FRONT PANEL CONFIGURATIONSINSTALLATIONDetach the yellow clamps located at the top and bottom of Shape and size of the base socket are slightly different with varioussocket types. ■DIN RAIL MOUNTINGSet the base socket so that its DIN rail adaptor is at the bot-tom. Position the upper hook at the rear side of base socket on the DIN rail and push in the lower. When removing the rail adaptor utilizing a minus screwdriver and pull.■WALL MOUNTING Refer to “EXTERNAL DI-MENSIONS.”TERMINAL CONNECTIONSConnect the unit as in the diagram below or refer to the connection diagram on the top of the unit.When an input resistor is provided with the module, attach it together with input wiring to the input screw terminals. ■EXTERNAL DIMENSIONS unit: mm (inch)CLAMP• When mounting, no extra space is needed between units.■CONNECTION DIAGRAM*Input shunt resistor attached for current input.U(+)V(–)■TERMINAL ASSIGNMENTS unit: mm (inch)INPUT RESISTORInput shunt resistor attached for current input.CHECKING1) Terminal wiring: Check that all cables are correctly con-nected according to the connection diagram.2) Power input voltage: Check voltage across the terminal 7 – 8 with a multimeter.3) Input: Check that the input signal is within 0 – 100% of the full-scale.4) Output: Check that the load resistance meets the de-scribed specifications.ADJUSTMENT PROCEDUREThis unit is calibrated at the factory to meet the ordered specifications, therefore you usually do not need any cali-bration.For matching the signal to a receiving instrument or in case of regular calibration, adjust the output as explained in the following.■HOW TO CALIBRATE THE OUTPUT SIGNALUse a signal source and measuring instruments of sufficient accuracy level. Turn the power supply on and warm up for more than 20 minutes.1) ZERO: Apply 0% input and adjust output to 0%.2) SPAN: Apply 100% input and adjust output to 100%.3) Check ZERO adjustment again with 0% input.4) When ZERO value is changed, repeat the above proce-dure 1) – 3).MAINTENANCERegular calibration procedure is explained below:■CALIBRATIONWarm up the unit for at least 20 minutes. Apply 0%, 25%, 50%, 75% and 100% input signal. Check that the output signal for the respective input signal remains within accu-racy described in the data sheet. When the output is out of tolerance, recalibrate the unit according to the “ADJUST-MENT PROCEDURE” explained earlier.LIGHTNING SURGE PROTECTIONM-System offers a series of lightning surge protector for protection against induced lightning surges. Please contact M-System to choose appropriate models.。