HES12-065180-1中文资料

A1203中⽂资料Continuous-time operation – Fast power-on time– Low noiseStable operation over full operating temperature range Reverse battery protectionSolid-state reliabilityFactory-programmed at end-of-line for optimum performance Robust EMC performance High ESD ratingRegulator stability without a bypass capacitorA1201, A1202, A1203 and A1204 Hall-effect bipolar switches are . The extensive on-board protection circuitry makes Continuous-Time Bipolar Switch FamilyFunctional Block DiagramVOUTTerminal ListName DescriptionNumberPackage LH Package UAVCC Connects power supply to chip 11VOUT Output from circuit 23GNDGround32Part Number Packing*MountingAmbient, T A B RP (Min)B OP (Max)A1201ELHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 85oC–5050A1201EUA-T Bulk, 500 pieces/bag 3-pin SIP through hole A1201LLHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 150oC A1201LUA-T Bulk, 500 pieces/bag 3-pin SIP through hole A1202ELHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 85oC–7575A1202EUA-T Bulk, 500 pieces/bag 3-pin SIP through hole A1202LLHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 150oC A1202LUA-T Bulk, 500 pieces/bag 3-pin SIP through hole A1203ELHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 85oC–9595A1203EUA-T Bulk, 500 pieces/bag 3-pin SIP through hole A1203LLHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 150oC A1203LUA-T Bulk, 500 pieces/bag 3-pin SIP through hole A1204ELHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 85oC–150150A1204EUA-T Bulk, 500 pieces/bag 3-pin SIP through hole A1204LLHLT-T 7-in. reel, 3000 pieces/reel 3-pin SOT23W surface mount –40oC to 150oCA1204LUA-TBulk, 500 pieces/bag3-pin SIP through hole*Contact Allegro for additional packing options.Product Selection GuideOPERATING CHARACTERISTICS over full operating voltage and ambient temperature ranges, unless otherwise noted Characteristic Symbol Test Conditions Min.Typ.Max.Units Electrical CharacteristicsSupply Voltage1V CC Operating, T J < 165°C 3.8–24V Output Leakage Current I OUTOFF V OUT = 24 V, B < B RP––10µA Output On Voltage V OUT(SAT)I OUT = 20 mA, B > B OP–215400mVPower-On Time2t PO Slew rate (dV CC/dt) < 2.5 V/µs, B > B OP + 5 G orB < B RP – 5 G––4µsOutput Rise Time3t r V CC = 12 V, R LOAD = 820 ?, C S = 12 pF––2µs Output Fall Time3t f V CC = 12 V, R LOAD = 820 ?, C S = 12 pF––2µsSupply Current I CCON B > B OP– 3.87.5mA I CCOFF B < B RP– 3.57.5mAReverse Battery Current I RCC V RCC = –30 V–––10mA Supply Zener Clamp Voltage V Z I CC = 10.5 mA; T A = 25°C32––V Supply Zener Current4I Z V Z = 32 V; T A = 25°C––10.5mA Magnetic Characteristics5Operate Point B OP A1201South pole adjacent to branded faceof device–401550G A1202–2675G A1203–2695G A1204–10042150GRelease Point B RP A1201North pole adjacent to branded faceof device–50–1540G A1202–75–26–G A1203–95–26–G A1204–150–40100GHysteresis B HYS A1201B OP – B RP53055G A12023052–G A12033052–G A12045082115G1 Maximum voltage must be adjusted for power dissipation and junction temperature, see Power Derating section.2 For V CC slew rates greater than 250 V/µs, and T A = 150°C, the Power-On Time can reach its maximum value.3 C S =oscilloscope probe capacitance.4 Maximum current limit is equal to the maximum I CC(max) + 22 mA.5 Magnetic flux density, B, is indicated as a negative value for north-polarity magnetic fields, and as a positive value for south-polarity magnetic fields. This so-called algebraic convention supports arithmetic comparison of north and south polarity values, where the relative strength of the field is indicated by the absolute value of B, and the sign indicates the polarity of the field (for example, a –100 G field and a 100 G field have equivalent strength, but opposite polarity).DEVICE QUALIFICATION PROGRAMContact Allegro for information.EMC (Electromagnetic Compatibility) REQUIREMENTSContact Allegro for information.THERMAL CHARACTERISTICS may require derating at maximum conditions, see application information CharacteristicSymbolTest ConditionsValue Units Package Thermal ResistanceR θJAPackage LH, minimum-K PCB (single layer, single-sided with copper limited to solder pads)110oC/W Package LH, low-K PCB (single layer, double-sided with 0.926 in 2 copper area)228oC/W Package UA, minimum-K PCB (single layer, single-sided with copper limited to solder pads)165oC/W678923451011121314151617181920212223242520406080100120140160180M a x i m u m A l l o w a b l e V C C (V )T=165oC;I =I Power Derating Curve V CC(min)V CC(max)100200300400500600700800900100011001200130014001500160017001800190020406080100120140160180Temperature (°C)P o w e r D i s s i p a t i o n ,P D (m W )Power Dissipation versus Ambient TemperatureCharacteristic DataFunctional DescriptionBipolar Device SwitchingThe devices of the A120X family provide highly sensitive switching for applications using magnetic fields of alternating polarities, such as ring magnets. There are three switching modes for bipolar devices, referred to as latch , unipolar switch , and negative switch . Mode is determined by the switchpoint charac-teristics of the individual device. The characteristic hysteresis, B HYS , of the device, is the difference in the relative magnetic strength and polarity of the switchpoints of the device. (Note that, in the following descriptions, a negative magnetic value indicates a north polarity field, and a positive magnetic value indicates a south polarity field. For a given value of magnetic strength, B X , the values –B X and B X indicate two fields of equal strength, but opposite polarity. B = 0 indicates the absence of a magnetic field.)Bipolar devices typically behave as latches. In this mode, magnetic fields of opposite polarity and equivalent strengths are needed to switch the output. When the magnetic fields are removed (B → 0) the device remains in the same state until a magnetic field of the opposite polarity and of sufficient strength causes it to switch. The hysteresis of latch mode behavior isshown in panel A of figure 1.In contrast to latching, when a device exhibits unipolar switch-ing, it only responds to a south magnetic field. The field must be of sufficient strength, > B OP , for the device to operate. When the field is reduced beyond the B RP level, the device switches back to the high state, as shown in panel B of figure 1. Devices exhibiting negative switch behavior operate in a similar but opposite manner. A north polarity field of sufficient strength, > B RP , (more north than B RP ) is required for operation, although the result is that V OUT switches high, as shown in panel C. WhenFigure 1. Bipolar Device Output Switching Modes. These behaviors can be exhibited when using a circuit such as that shown in panel D. Panel A displays the hysteresis when a device exhibits latch mode (note that the B HYS band incorporates B= 0), panel B shows unipolar switch behavior (the B HYS band is more positive than B = 0), and panel C shows negative switch behavior (the B HYS band is more negative than B = 0). Bipolar devices, such as the 120x family, can operate in any of the three modes.HYS V O U THYS HYSV OUT(SAT)CC(A)(B)(C)(D)the field is reduced beyond the B OP level, the device switches back to the low state.The typical output behavior of the A120x devices is latching. That is, switching to the low state when the magnetic field at the Hall sensor exceeds the operate point threshold, B OP . At this point, the output voltage is V OUT(SAT). When the magnetic field is reduced to below the release point threshold, B RP , the device output, V OUT , goes high. The values of the magnetic parameters are specified in the Magnetic Characteristics table, on page 3. Note that, as shown in figure 1, these switchpoints can lie in either north or south polarity ranges.The A120x family is designed to attain a small hysteresis, and thereby provide more sensitive switching. Although this means that true latching behavior cannot be guaranteed in all cases, proper switching can be ensured by use of both south and north magnetic fields, as in a ring magnet. The hysteresis of the A120x family allows clean switching of the output, even in the presence of external mechanical vibration and electrical noise.Bipolar devices adopt an indeterminate output state when pow-ered-on in the absence of a magnetic field or in a field that lies within the hysteresis band of the device.For more information on Bipolar switches, refer to Application Note 27705, Understanding Bipolar Hall Effect Sensors . CONTINUOUS-TIME BENEFITSContinuous-time devices, such as the A120x family, offer the fastest available power-on settling time and frequency response. Due to offsets generated during the IC packaging process, continuous-time devices typically require programming after packaging to tighten magnetic parameter distributions. In con-trast, chopper-stabilized switches employ an offset cancellation technique on the chip that eliminates these offsets without the need for after-packaging programming. The tradeoff is a longer settling time and reduced frequency response as a result of the chopper-stabilization offset cancellation algorithm.Figure 2. Continuous-Time Application, B < B RP .. This figure illustrates the use of a quick cycle for chopping V CC in order to conserve battery power. Position 1, power is applied to the device. Position 2, the output assumes the correct state at a time prior to the maximum Power-On Time, t PO(max). The case shown is where the correct output state is HIGH . Position 3, t PO(max) has elapsed. The device output is valid. Position 4, after the output is valid, a control unit reads the output. Position5, power is removed from the device.VV PO(max)The choice between continuous-time and chopper-stabilized designs is solely determined by the application. Battery manage-ment is an example where continuous-time is often required. In these applications, V CC is chopped with a very small duty cycle in order to conserve power (refer to figure 4). The duty cycleis controlled by the power-on time, t PO, of the device. Because continuous-time devices have the shorter power-on time, they are the clear choice for such applications.For more information on the chopper stabilization technique, refer to Technical Paper STP 97-10, Monolithic Magnetic Hall Sensor Using Dynamic Quadrature Offset Cancellation and Technical Paper STP 99-1, Chopper-Stabilized Amplifiers with a Track-and-Hold Signal Demodulator.ADDITIONAL APPLICATIONS INFORMATION Extensive applications information for Hall-effect sensors is available in:Hall-Effect IC Applications Guide, Application Note 27701 Hall-Effect Devices: Gluing, Potting, Encapsulating, Lead Welding and Lead Forming, Application Note 27703.1Soldering Methods for Allegro’s Products – SMT and Through-Hole, Application Note 26009All are provided in Allegro Electronic Data Book, AMS-702, and the Allegro Web site,/doc/407cd0b7c77da26925c5b0c1.html .Power Derating Power DeratingThe device must be operated below the maximum junction temperature of the device, T J(max). Under certain combinations of peak conditions, reliable operation may require derating sup-plied power or improving the heat dissipation properties of the application. This section presents a procedure for correlating factors affecting operating T J. (Thermal data is also available on the Allegro MicroSystems Web site.)The Package Thermal Resistance, RθJA, is a figure of merit sum-marizing the ability of the application and the device to dissipate heat from the junction (die), through all paths to the ambient air. Its primary component is the Effective Thermal Conductivity, K, of the printed circuit board, including adjacent devices and traces. Radiation from the die through the device case, RθJC, is relatively small component of RθJA. Ambient air temperature,T A, and air motion are significant external factors, damped by overmolding.The effect of varying power levels (Power Dissipation, P D), can be estimated. The following formulas represent the fundamental relationships used to estimate T J, at P D.P D = V IN× I IN (1)T = P D× RθJA(2)T J = T A + ?T (3)For example, given common conditions such as: T A= 25°C,V CC = 12 V, I CC = 4 mA, and RθJA = 140 °C/W, then:P D = V CC× I CC = 12 V × 4 mA = 48 mWT = P D× RθJA = 48 mW × 140 °C/W = 7°CT J = T A + ?T = 25°C + 7°C = 32°CA worst-case estimate, P D(max), represents the maximum allow-able power level (V CC(max), I CC(max)), without exceeding T J(max), at a selected RθJA and T A.Example: Reliability for V CC at T A =150°C, package UA, using minimum-K PCB.Observe the worst-case ratings for the device, specifically:RθJA =165°C/W, T J(max) =165°C, V CC(max) =24 V, andI CC(max) =7.5mA.Calculate the maximum allowable power level, P D(max). First, invert equation 3:T max = T J(max) – T A = 165°C–150°C = 15°CThis provides the allowable increase to T J resulting from internal power dissipation. Then, invert equation 2:P D(max) = ?T max ÷ RθJA = 15°C ÷ 165 °C/W = 91 mWFinally, invert equation 1 with respect to voltage:V CC(est) = P D(max) ÷ I CC(max) =91 mW ÷ 7.5 mA = 12.1 VThe result indicates that, at T A, the application and device can dissipate adequate amounts of heat at voltages ≤V CC(est). Compare V CC(est) to V CC(max). If V CC(est)≤ V CC(max), then reli-able operation between V CC(est) and V CC(max) requires enhanced RθJA. If V CC(est)≥ V CC(max), then operation between V CC(est) and V CC(max) is reliable under these conditions.Package LH, 3-Pin (SOT-23W)Package UA, 3-PinThe products described herein are manufactured under one or more of the following U.S. patents: 5,045,920; 5,264,783; 5,442,283; 5,389,889; 5,581,179; 5,517,112; 5,619,137; 5,621,319; 5,650,719; 5,686,894; 5,694,038; 5,729,130; 5,917,320; and other patents pending.Allegro MicroSystems, Inc. reserves the right to make, from time to time, such de p ar t ures from the detail spec i f i c a t ions as may be required to permit improvements in the per f or m ance, reliability, or manufactur-ability of its products. Before placing an order, the user is cautioned to verify that the information being relied upon is current.Allegro products are not authorized for use as critical components in life-support devices or sys t ems without express written approval.The in f or m a t ion in c lud e d herein is believed to be ac c u r ate and reliable. How e v e r, Allegro MicroSystems, Inc. assumes no re s pon s i b il i t y for its use; nor for any in f ringe m ent of patents or other rights of third parties which may result from its use.Copyright ? 2005, Allegro MicroSystems, Inc.。

259EncodersMetal ShaftInsulatedShaftThroughShaft TypeRing TypeStandard Codes 1. The ●marks shows the ON position.2. The ●marks ： Connections between terminals and the 5 （COM） are ON.Waterproof PropertyImmersion of encoder, not in operation, in water at depth of 1m at normal temperature for 30 minutes.EC18AGAPosition No.123456789101112Rotation angle （° ）3060901201501802102402703003301●●●●●●2●●●●3●●●●●●4●●●●5（COM ）●●●●●●●●●●●●T E R M I N A L N O .EC18AGB20401Position No.12345678910111213141516Rotation angle （° ）22.54567.590112.5135157.5180202.5225247.5270292.5315337.51●●●●●●●●2●●●●●●●●3●●●●●●●●4●●●●●●●●5（COM ）●●●●●●●●●●●●●●●●T E R M I N A L N O .EC18AGB20407Position No.123456789101112131415Rotation angle （° ）244872961201441681922162402642883123361●●●●●●●●2●●●●●●●●3●●●●●●●●4●●●●●●●●5（COM ）●●●●●●●●●●●●●●●T E R M I N A L N O .EC18A ／18mm Size Insulated Shaft Type（Two phase A and B ）275EncodersMetal ShaftInsulated Shaft Through Shaft TypeRing Type1. When using an infrared reflow oven, solder may sometimes not be applied. Be sure to use a hot air reflow oven or a type that uses infrared rays in combination with hot air.2. The temperatures given above are the maximum temperatures at the terminals of the encoder when employing a hot air reflow method. The temperature of the PC board and the surface temperature of the encoder may vary greatly depending on the PC board material, its size and thickness. Ensure that the surface temperature of the encoder does not rise to 250℃ or greater.3. Conditions vary to some extent depending on the type of reflow bath used. Be sure to give due consideration to this prior to use.NotesEC05E EC21CEC28C, EC35CH250℃ min.230℃ to 245℃260℃230℃ min.220℃ 230℃180℃200℃180℃150℃150℃150℃60s to 120s 60s to 120s 2 min. min.ーー3s30s to 40s 25s to 60s40sー300s max.230s max.2 times max.1 time max.1 time max.Soldering surfacetemperatureSoldering temperatureHeating timeSoldering timeNo. of soldersEC09E, EC111, EC11E, EC11M, EC11N, EC18A,EC21A, EC28A, EC35A, EC35AH, EC50A Series100℃ max.260±5℃2 min. max.5±1s 2 times max.PreheatingDip solderingReference for Dip SolderingExample of Reflow Soldering ConditionReference for Manual SolderingEC10E, EC12D, EC12E EM11BEC40A100℃ max.100℃ max.110℃ max.260±5℃260℃ max.260℃ max.1 min. max.1 min. max.1 min. max.3±1s 3s max.10s max.2 times max.2 times max.1 timeTemperature profile300200100A BC Time (s)G max.F max.H max.E max.RoomtemperatureT e m p e r a t u r e (˚C )Pre-heating DEncoders / Soldering ConditionsEC05E, EC09E, EC10E, EC111, EC11E, EC11M, EC11N, EC12D, EC12E, EC18A, EC21A, EC28A, EC35A, EC35AH, EC40A, EC50A, EM11B, EC21C, EC28C, EC35CHSeries350℃ max.3s max. 1 timeTip temperatureSoldering timeNo. of soldersSeries ABCDEFGHNo. of reflows。

61851-1 Product DetailsHome | Customer Support | Suppliers | Site Map | Privacy Policy | Browser Support© 2008 Tyco Electronics Corporation All Rights Reserved SearchProducts Documentation Resources My Account Customer SupportHome > Products > By Type > FASTON Electrical Quick Connects > Product Feature Selector > Product Details61851-1TE Part Number: 61851-1ActiveAdd to Part ListView 3D PDF Multiple Circuit Housings with Tabs &Receptacles Including FASTIN-FASTONAlways EU RoHS/ELV Compliant (Statement of Compliance)Product Highlights:?Tab?Tab Fit = 6.35 x 0.81 mm?Wire Range = 0.80-2.00²[18-14] mm[AWG]?Insulation Diameter = 3.05-4.32[.120-.170] mm [in]?Wire/Cable Type = Regular WireView all Features | Find SimilarProductsCheck Pricing &AvailabilitySearch for ToolingProduct FeatureSelectorContact Us AboutThis ProductQuick LinksDocumentation & Additional InformationProduct Drawings:?TAB, FASTIN-FASTON, 6.35 [.250] SERIES (SPECIAL DOUB...(PDF, English)Catalog Pages/Data Sheets:?None AvailableProduct Specifications:?None AvailableApplication Specifications:?None AvailableInstruction Sheets:?None AvailableCAD Files: (CAD Format & Compression Information)?2D Drawing (DXF, Version J1)?3D Model (IGES, Version J1)?3D Model (STEP, Version J1)List all Documents Additional Information:?Product Line InformationRelated Products:?ToolingProduct Features (Please use the Product Drawing for all design activity)Product Type Features:?Product Type = Tab?Tab Fit (mm [in]) = 6.35 x 0.81 [.250 x .032]?Insulation Diameter (mm [in]) = 3.05-4.32[.120-.170]?Wire/Cable Type = Regular Wire?Finish = Tin?Material = Brass?Insertion Force = Normal?Insulation Support = With?Crimp Type = F-Crimp?FASTON = Yes?For Housing Type = Multiple?Comment = Double tab Body Related Features:?Wire Range (mm [AWG]) = 0.80-2.00²[18-14] ?Stock Thickness (mm [in]) = 0.81 [0.032]Industry Standards:?RoHS/ELV Compliance = RoHS compliant, ELVcompliant?Lead Free Solder Processes = Not relevant forlead free process?RoHS/ELV Compliance History = Always wasRoHS compliantPackaging Related Features:?Packaging Method = StripOther:?Line = FASTIN-FASTON .250?Brand = AMPProvide Website Feedback | Need Help?。

镍基合金管Corrosion Resistant Alloy Pipe：主要钢级/钢号Designation:Monel 400 (UNS N04400) ,UNS N02201，Incoloy600(UNS N06600), N6 (UNS N02200)，UNS N08800 , UNS N08810, UNSN06025，UNS N08825 ,UNS N10276, UNS N06022，UNS N08811, UNS N06059,UNS N10001，UNS N10665, UNS N06625, UNS N08028，UNSN06690, UNS N06601, UNS N06455等。

执行标准Standards: GB15011 ，JB4742，ASME SB-161 ASME SB-163，ASME SB-165 ，ASME SB-167，ASME SB - 622规格范围:外径（OD）：3.18~114.3mm , 壁厚（WT）:0.5~7.11mm, 长度（L）:≤18000mm各标准材质对应表Material designation:材料化学成分、密度、用途等。

GH4145 ( Inconel X-750 / UNS N07750 / W.Nr. 2.4669 / NiCr15Fe7TiAl / AFNOR NC15TNbA )化学成分：Cr:14.0~17.0Ni+Co:≥70.0Al:0.4~1.00Ti:2.25~2.75C≤0.08Mn≤1.00P≤0.015S≤0.01Fe：5.0~9.0密度：8.3 g/cm3性能通途：在980℃以下有足够强度及抗腐蚀氧化性，是高强度弹簧优先选择材料，适于制作弹性膜片和弹性密封件。

GH4169 ( Inconel 718 / UNS N07718 / W.Nr. 2.4668 / NiCr19Fe19Nb5Mo3 / NA51 / AFNOR NC19FeNb )化学成分：C：≤0.08，Cr：17.0～21.0，Ni：50~55，Co：≤1.00，Mo：≤2.8~3.30，Al：0.20～0.8，Ti：0.65～1.15，Fe：余，Nb：4.75～5.50，B：≤0.006，Mn：≤0.35，Si：≤0.35，S：≤0.015，Cu：≤0.30，P：≤0.015，Mg:≤0.01密度：8.2 g/cm3性能通途：为奥氏体结构，沉淀硬化后产生的“γ”相使之具有优秀的机械性能，由于在700℃时具有高温强度和优秀的耐腐蚀性和易加工性，广泛应用于各种耐高温要求的场合。

炉
炉。

⒉炉冷通常指以30-50℃／小时冷却，冷却到300℃以下空冷。

附表说明:
25-27号应炉冷到150℃以下出 ⒈表中注明“完退”即完全退火；“不完退”即不完全退火； 即软化退火；“退”即快速退火；回归即回归处理。

“等退”即等温退火；“时效”即时效处理；“软退”
毫 3.34、38号铸造铝合金不允许在硝盐槽中加热，淬火后不允
度（毫米）
许加热到100℃以上，30铜及镁在上限时，应在515℃淬火； ⒍表中的时间为大概数；钛合金淬火保温时间t1为：
米，D为有效厚度（毫米）
⒋46号预先加热是铸件厚度大于12毫米，62、63号的加热时 间指1毫米左右的时间，最好用氩气或氨气保护加热。

空冷。

t1＝（5-8）＋AD（分），A为系数3分／毫米，D为有效厚 完全退火时间t为t＝15＋AD（分）A为保温系数1-1.5分／ 含镁更高时，应在500℃淬火。

⒌铜及其合金的除应力处理，通常为200-300℃1-2小时保温
淬火；时
＿
.。

SA12中⽂资料SA5.0thruSA170AFEATURES:ECONOMICAL SERIESAVAILABLE IN BOTH UNIDIRECTIONAL AND BI-DIRECTIONAL CONSTRUCTION 5.0 TO 170 STAND-OFF VOLTAGE AVAILABLE ? 500 WATTS PEAK PULSE POWER DISSIPATION ?QUICK RESPONSEDESCRIPTION:This Transient Voltage Suppressor is an economical, molded, commercial product used to protect voltage sensitive components from destruction or partial degradation.The response time of their clamping action is virtually instantaneous (1 x 10-12seconds) and they have a peak pulse power rating of 500 watts for 1 ms as depicted in Figure 1 and 2. Microsemi also offers a great variety of other Transient Voltage Suppressor's to meet higher and lower power demands and special applications. MAXIMUM RATINGS:Peak Pulse Power Dissipation at 25°C: 500 WattsSteady State Power Dissipation: 2.5 Watts at T L = +75°C3/8" Lead Lengtht clamping (0 volts to BV Min.):Unidirectional <1x10-12 Seconds: Bi-directional <5x10-9Seconds.Operating and Storage Temperature: -55° to +175°C8700 E. Thomas Road Scottsdale, AZ 85252Phone: (480) 941-6300Fax: (480) 947-15035.0 thru 170 volts500 Watts Transient Voltage Suppressors2 x ?.032 ± .002[.81 ± .05].107[2.72]max.POLARITYMark {cathode}.205[5.21]MAX.NOTE: DIMENSIONS IN [ ] =MILLIMETERSP E A K P U L S E P O W E R (P p p ) O R C O N T I N U O U S P O W E R I N P E R C E N T O F 25°C R A T I N G FIGURE 1DERATING CURVE50100150175255075100TYPICAL CHARACTERISTIC CURVEST L LEAD TEMPERATURE °CPulse Time Duration (tp) is Defined as that point where Ip decaysto 50% of I surgePeak Value Ipp 100501234TIME (t) IN MILLISECONDSFIGURE 2PULSE WAVEFORM FOR EXPONENTIAL SURGEP U L S E C U R R E N T I N P E R C E N T O F I p pMECHANICALCHARACTERISTICSCASE: Void free transfer molded thermosetting plastic.FINISH: Readily solderable.POLARITY: Band denotes cathode. Bi-directional not marked.WEIGHT: 0.7 gram (Appx.).MOUNTING POSITION: AnyDO-412 X1.10[27.94]MIN.SA170A ELECTRICAL CHARACTERISTICS AT 25°C PART NUMBERBREAKDOWNVOLTAGE V(BR)MIN.MAXTESTCURRENTI TRATEDSTANDOFFVOLTAGEV WMMAX. REVERSESTANDBYCURRENTI D @V WMMAX.PEAKREVERSEVOLTAGEV C MAX.@ I PPMAX. PEAKPULSECURRENTI PP(Figure 2)MAX.TEMP.COEFFICIENTOF V(BR)-55°C TOαV(BR) VOLTS VOLTS mA VOLTSµ ADC VOLTS AMP% / °CSA5.0 6.407.3010 5.06009.652.057 SA5.0A 6.407.0010 5.06009.254.3.057 SA6.0 6.678.1510 6.060011.443.9.059 SA6.0A 6.677.3710 6.060010.348.5.059 SA6.57.228.8210 6.540012.340.7.061 SA6.5A7.227.9810 6.540011.244.7.061SA7.07.789.51107.015013.337.8.065 SA7.0A7.788.60107.015012.041.7.065 SA7.58.3310.217.55014.335.0.067SA7.5A8.339.2117.55012.938.8.067 SA8.08.8910.918.02515.033.3.070 SA8.0A8.899.8318.02513.636.7.070SA8.59.4411.518.5515.931.4.073 SA8.5A9.4410.418.5514.434.7.073 SA9.010.012.219.0116.929.5.076SA9.0A10.011.119.0115.432.5.076 SA1011.113.6110118.826.6.078 SA10A11.112.3110117.029.4.078SA1112.214.9111120.124.9.081 SA11A12.213.5111118.227.4.081 SA1213.316.3112122.022.7.082SA12A13.314.7112119.925.1.082 SA1314.417.6113123.821.0.084 SA13A14.415.9113121.523.2.084SA1415.619.1114125.819.4.086 SA14A15.617.2114123.221.5.086 SA1516.720.4115126.918.8.087SA15A16.718.5115124.420.6.087 SA1617.821.8116128.817.6.088 SA6A17.819.7116126.019.2.088SA1718.923.1117130.516.4.090 SA17A18.920.9117127.618.1.090 SA1820.024.4118132.215.5.092SA18A20.022.1118129.217.2.092 SA2022.227.1120135.813.9.093 SA20A22.224.5120132.415.4.093thruSA170A ELECTRICAL CHARACTERISTICS AT 25°CPART NUMBERBREAKDOWNVOLTAGE V(BR)MIN.MAXTESTCURRENTI TRATEDSTANDOFFVOLTAGEV WMMAX. REVERSESTANDBYCURRENTI D @V WMMAX.PEAKREVERSEVOLTAGEV C MAX.@ I PPPULSECURRENTI PP(Figure 2)MAX.TEMP.COEFFICIENTOF V(BR)-55°C TO175°CαV(BR) VOLTS VOLTS mA VOLTSµ ADC VOLTS AMP% / °CSA2224.429.8122139.412.7.094 SA22A24.426.9122135.514.1.094 SA2426.732.6124143.011.6.096SA24A26.729.5124138.912.8.096 SA2628.935.3126146.610.7.097 SA26A28.931.9126142.111.9.097SA2831.138.0128150.09.9.098 SA28A31.134.4128145.411.0.098 SA3033.340.7130153.59.3.099SA30A33.336.8130148.410.3.099 SA3336.744.9133159.08.5.100 SA33A36.740.6133153.39.4.100SA3640.048.9136164.37.8.101 SA36A40.044.2136158.18.6.101 SA4044.454.3140171.47.0.101SA40A44.449.1140164.57.8.101 SA4347.858.4143176.7 6.5.102 SA43A47.852.8143169.47.2.102 SA4550.061.1145180.3 6.2.102 SA45A50.055.3145172.7 6.9.102 SA4853.365.1148185.5 5.8.103 SA48A53.358.9148177.4 6.5.103SA5156.769.3151191.1 5.5.103 SA51A56.762.7151182.4 6.1.103 SA5460.073.3154196.3 5.2.104SA54A60.066.3154187.1 5.7.104 SA5864.478.71581103.0 4.9.104 SA58A64.471.2158193.6 5.3.104SA6066.781.51601107.0 4.7.104 SA60A66.773.7160196.8 5.2.104 SA6471.186.91641114.0 4.4.105SA64A71.178.61641103.0 4.9.105 SA7077.895.11701125.0 4.0.105 SA70A77.886.01701113.0 4.4.105SA7583.3102.01751134.0 3.7.105 SA75A83.392.11751121.0 4.1.105thruSA170A ELECTRICAL CHARACTERISTICS AT 25°CPART NUMBERBREAKDOWNVOLTAGE V(BR)MIN.MAXTESTCURRENTI TRATEDSTANDOFFVOLTAGEV WMMAX. REVERSECURRENTI D @V WMMAX.PEAKREVERSEVOLTAGEV C MAX.@ I PPMAX. PEAKPULSECURRENTI PP(Figure 2)MAX.TEMP.COEFFICIENTOF V(BR)-55°C TO175°CαV(BR) VOLTS VOLTS mA VOLTSµ ADC VOLTS AMP% / °CSA7886.7106.01781139.0 3.6.106 SA78A86.795.81781126.0 4.0.106 SA8594.4115.01851151.0 3.3.106SA85A94.4104.01851137.0 3.6.106 SA90100.0122.01901160.0 3.1.107 SA90A100.0111.01901146.0 3.4.107SA100111.0136.011001179.0 2.8.107 SA100A111.0123.011001162.0 3.1.107 SA110122.0149.011101196.0 2.6.107SA110A122.0135.011101177.0 2.8.107 SA120133.0163.011201214.0 2.3.107 SA120A133.0147.011201193.0 2.0.107SA130144.0176.011301231.0 2.2.108 SA130A144.0159.011301209.0 2.4.108 SA150167.0204.011501268.0 1.9.108SA150A167.0185.011501243.0 2.1.108 SA160178.0218.011601287.0 1.7.108 SA160A178.0197.011601259.0 1.9.108SA170189.0231.011701304.0 1.6.108 SA170A189.0209.011701275.0 1.8.108 Note: For Bi-directional construction, indicate a C or CA suffix after the part number, i.e. SA5.0CAthru SA170A10010C -C A P A C I T A N C E - P I C O F A R AD S1001001000V (BR)- BREAKDOWN VOLTAGE - VOLTSFIGURE 3TYPICAL CAPACITANCE VS BREAKDOWN VOLTAGE107.05.03.02.01.00.70.50.30.20.10.11.010********0.20.5 2.0 5.020*********tw - Pulse Width µsFIGURE 4PEAK PULSE POWER VS. PULSE TIME(P P P ) - P e a k P u l s e P o w e r , (k W )20305070。

上海商虎/张工：158 –0185 -9914HAl60-1-1铝黄铜HAl60-1-1铝铜管HAl60-1-1黄铜材料名称：铝黄铜挤制棒(10～120mm)商标：HAl60-1-1标准：GB/T 13808-1992特性及适用范围：具有高的强度,在大气、淡水和海水中的耐蚀性好，但对腐蚀决裂敏感，在热态下压力加工性好，冷态下可塑性低。

化学成份：铜 Cu ：58.0～61.0锌 Zn：余量铅 Pb：≤0.40磷 P：≤0.01铝 Al：0.70～1.50铁 Fe：0.70～1.50锰 Mn：0.1～0.6锑 Sb ：≤0.005铋 Bi：≤0.002注：≤0.7(杂质)我司专业的合金铜制品生产、可供应铜及铜合金、铜镍合金、铬锆铜、铍青铜、锡青铜、无氧铜、铝青铜、黄铜、铝黄铜、铅黄铜、锡黄铜、硅青铜、磷脱氧铜、钨铜等。

铜镍合金/白铜：BFe 30-1-1（C71500）、BFe 10-1-1（C70600）、B30、BMn 40-1.5、NCu 40-2-1、BZn18-18等铬锆铜：QZr 0.2、QCr 0.4、QZr 0.5等铍青铜：QBe 1.9、QBe2、C17200、C17300、C17500、C17510、CuNi2Be等锡青铜：QSn 1.5-0.2、QSn4-3、QSn4-4-4、QSn6.5-0.1、QSn6.5-0.4、QSn7-0.2、QSn8-0.3、Qsn10-1等无氧铜/磷脱氧铜/钨铜：TU0、TU1、TU2、TP1、TP2、W1、CuW50、W55、W60、W70、W75、W85、CuW90等锡黄铜/铝黄铜HSn 60-1、HSn62-1、HSn70-1、HSn 90-1、HAl 77-2、HAl67-2.5等铝青铜：QAl 5、QAl9-2、QAl9-4、QAl10-3-1.5、QAl10-4-4、QAl 10-5-5等铅黄铜/硅青铜：HPb 59-1、HPb60-2、HPb62-3、HPb63-1、HPb63-3等QSi 1-3、QSi3-1、HSi 80-3等产品广泛应用于海水淡化、核电、石油化工、船舶、汽轮机发电、压力容器、热交换器、中央空调及铁路、城轨交通等领域。

镀钛优点：耐磨性更高，模具寿命大大延长胶料的可流动时间更长，填模效果更佳塑料产品表面质量提高，不良率降低脱模更容易，甚至可避免使用脱模剂有效防止腐蚀性原料侵蚀模具基体模具易于清洁，且清洁周期更长塑料模具由于其结构复杂决定了加工难度大，故造价相对较高，所以提高模具的寿命就是一个主要课题，尤其镜面和蚀纹面，就特别容易磨损，这一直是一件令人十分苦恼的事情。

经过真空涂层的塑料模具表面硬度的提高，使得抗磨耗性显著提高；而且因模具表面光洁度的增强和摩擦系数的降低使得胶料的流动性更好以及塑料产品更易脱模。

同时真空涂层更因其特殊的晶格结构在模具表面形成致密的保护层，可以非常有效的解决腐蚀的弊病。

更为重要的是，由于我们的涂层完全不会改变模具的表面状况，无论是镜面还是蚀纹面，甚至要求极高的CD模具.纳米镀钛的基本条件:1.热处理回火温度：SLD﹑SKD﹑SKH,钨刚等各种经热处理后的钢材,必须高温回火,回火处理,温度最好为500℃以上.2.工作表面不可有锈斑﹑黑皮存在,且工件不得有焊补过.3.若工件为组合件,须将工件拆开成单件来处理.4.工作面其光泽度要求为0.2~0.4.注︰表面光泽度影响其附着力﹐光泽度越好其附着力越强﹐模具的使用寿命越長.5.欲留模具﹑冲棒的公差.纳米镀钛膜厚为3um~4um(双边)长江科技（东莞）镀钛厂建于2002年，长年经营：PVD纳米镀钛通常称谓：纳米镀钛，纳米镀钛厂，东莞纳米镀钛，镀膜,真空纳米镀钛,氮化钛，纳米镀钛加工，PVD，表面处理，钛板，表面处理纳米镀钛加工,真空镀钛加工，表面处理，PVD涂层，模具纳米镀钛，纳米涂层，真空纳米电镀，零件纳米镀钛，精密模具纳米镀钛，冲压模具纳米镀钛，压铸模具纳米镀铬，耐磨涂层，超硬纳米镀钛，镀钛涂层，离子镀钛，纳米涂层，冲棒纳米镀钛，五金模具纳米镀钛，塑胶模纳米镀钛，纳米镀钛,金属纳米镀钛表面处理等. 金属表面处理PVD纳米镀钛特点：增寿、增硬、增值,并以其硬高度、高耐磨、强抗腐蚀性、抗高温、抗黏着性等优越的使用性能广泛应用于模具类,刀具类,冲具类,工具类等模具工业中。

常用表处理,热处理对照表,中文,日文,对照
中文英文日文
参考镀层厚度(μm)
颜色类型硬铬Icr,HCr,10-20银白表面处理装饰铬Cr 5-10银白表面处理阳极氧化（白色）SA(W)3-6带光泽的白色表面处理阳极氧化（黑色）
SA(BL)10-30带光泽的黑色
表面处理磷化SCHP 5-15黑色表面处理发黑SOB 1-5黑色表面处理电解镍E-Ni 3-10白黄表面处理化学镍Ni 8-11白黄表面处理蓝白锌Zn-CMI 5-10
青白表面处理烤漆P(SV)银色
表面处理高频淬火HQI 热处理抛光研磨buff 机加工氮化处理HNTS 10-30
灰色
表面处理本色硬质氧化SH(W)两种：白色，黑色
表面处理高频淬火+回火HQ-HT 热处理碳氮共渗HNT
100-200
热处理黑色硬质氧化
表面处理
常用符号对照表
备注
灰色。

DNA Demo Kit, Part Number 5061-6051(707) 577-3000营业时间 早8：00-下午5：00化学品安全技术说明书GHS产品标识符紧急电话号码（带值班时间）::供应商/ 制造商:Keysight Technologies, Inc.1400 Fountaingrove Parkway Santa Rosa, California 95403DNA Demo Kit, Part Number 5061-6051物质或混合物相关的确定的用途和使用防止建议Lambda DNA, EcoR1 Digest in 1X Tris-EDTA Buffer, Part Number 8500-85368500-8536Magnesium Chloride Concentrate, Part Number 8500-85388500-8538HEPES Buffer Concentrate: 100mM HEPES , Part Number 8500-85398500-8539Nickel Chloride Concentrate: 100 mM NiCl, Part Number 8500-85408500-8540产品号:物质用途:分析化学。

Lambda DNA, EcoR1 Digest in 1X Tris-EDTA Buffer, Part Number 8500-8536无规定。

Magnesium ChlorideConcentrate, Part Number 8500-8538无规定。

HEPES Buffer Concentrate: 100mM HEPES, Part Number 8500-8539无规定。

Nickel Chloride Concentrate:100 mM NiCl, Part Number 8500-8540呼吸或皮肤过敏——呼吸 - 1呼吸或皮肤过敏——皮肤 - 1生殖细胞致突变性 - 2致癌性 - 1A生殖毒性 (未出生儿童) - 1B特异性靶器官系统毒性反复接触 - 1危害水生环境—急性危险 - 3危害水生环境—慢性危险 - 3物质或混合物的分类:Lambda DNA, EcoR1 Digest in 1X Tris-EDTA Buffer, Part Number 8500-8536混合物中由毒性未知的组分组成的比率： 100%Magnesium ChlorideConcentrate, Part Number 8500-8538不适用。

通用管HES B 122-00(版本号：1)1．适用范围本标准规定了标准的通用管（*1）（以下简称管）。

注（*1）：通用管主要用于配气（包括油和汽油），通常为增压管，通风管，溢流管和通气管。

备注：本标准所采用的单位及数值，是SI（国际单位系统）的标准值，标有{ }的是惯用单位对应的值。

2．类型根据材料成分和颜色，管的分类见表1。

表1注：（*2）：产品标注符合第4项规定，这些代码也可按要求使用。

（*3）：允许汽油短暂流动。

例：燃油溢流管（*4）：允许机油短暂流动。

例：机油排放管（*5）；此数值不是测试温度，而是实际运行温度。

（*6）；T-A1管指减去外径的T-A管（例：CHC材料的薄层）。

T-A1将被禁用，因此不要使用T-A1。

如果非要用T-A1，请先和本田研究所材料分析部协商。

3．尺寸管的尺寸见表2和表3。

表2备注：1．不要使用（）的值，除非有特别要求。

2．负压系统管和接头的接合参考HES A 1077 {管和接头的接合[适用于空气系统（负压）]}。

4．标注和零件号标注：管，（I.D. x 长度）例：管，8 x 250…………95005-80250-10零件号：注（*7）：橙色参考“Munsell系统”5Y 8.5/12。

6．标志6.1 管上必须有以下信息（不包括T-K）。

（1）制造年/月年以现今历法的最后两位数表示，月份以数字形式印在管上。

（单位数月份以0开头。

）年月按顺序印刷，中间不隔开。

（2）制造商名称（或代码）制造商名称（或代码）印在管的识别码后，前面用连字符连接。

（3）管识别码使用第5节规定的管识别码。

T-A管增加一白色条纹。

6.2 印刷尺寸6.4 印刷质量不得脱色或褪色。

6.5 其它参考附录中的管道标志表示法的标准。

7．图纸规定符合本标准的零件，不绘制零件图。

8．品质8.1橡胶材料管橡胶材料的质量必须符合表4的要求。

表4-2(材料)注：（*8）；仅适用于Φ5.3 I.D.的T-A1管；外部和内部橡胶的硬度和T-A的相同。

哈氏合金(Hastelloyalloy)一、引言哈氏合金是镍基合金的一种，目前主要分为B、C、G三个系列，它主要用于铁基Cr-Ni或Cr-Ni-Mo不锈钢、非金属材料等无法使用的强腐蚀性介质场合，在国外已广泛应用于石油、化工、环保等诸多领域。

其牌号和典型使用场合如下表所示。

为改善哈氏合金的耐蚀性能和冷、热加工性能，哈氏合金先后进行了三次重大改进，其发展过程如下：B系列：B →B-2(00Ni70Mo28) →B-3C系列：C →C-276(00Cr16Mo16W4) →C-4(00Cr16Mo16) →C-22(00Cr22Mo13W3) →C-2000(00Cr20Mo16)G系列：G →G-3（00Cr22Ni48Mo7Cu）→G-30(00Cr30Ni48Mo7Cu)目前使用最广泛的是第二代材料N10665(B-2)、N10276(C-276)、N06022(C-22)、N06455(C-4)和N06985(G-3)。

第三代材料N10675(B-3)、N10629(B-4)、N06059(C-59)处于推广阶段。

由于冶金技术的进步，近年来出现了多个牌号的含~6%Mo的所谓“超级不锈钢”，替代了G系列合金，使得G系列合金的生产和使用迅速下降。

二、典型哈氏合金化学成分三、力学性能哈氏合金的力学性能非常突出，它具有高强度、高韧性的特点，所以在机加工方面有一定的难度，而且其应变硬化倾向极强，当变形率达到15%时，约为18-8不锈钢的两倍。

哈氏合金还存在中温敏化区，其敏化倾向随变形率的增加而增大。

当温度较高时，哈氏合金易吸收有害元素使它的力学性能和耐腐蚀性能下降。

材料的力学性能四、常用哈氏合金1：Hastelloy B-2alloy(哈氏B-2合金)一、耐蚀性能哈氏B-2合金是一种有极低含碳量和含硅量的Ni-Mo合金，它减少了在焊缝及热影响区碳化物和其他相的析出，从而确保即使在焊接状态下也有良好的耐蚀性能。

HSn60-1黄铜成分介绍
康女士15 3 - 1 62 o - 5 88 6
HSn60-1锡黄铜性能与HSn62-1相近，极好的热加工性能，可焊性能.耐蚀性能和冷加工性能好，主要产品为线材
中文名称
HSn60-1锡黄铜
标准
GB/T 14954-1994
抗拉强度
≥315伸长率δ10
热处理规范
热加工温度760～800℃
材料标准：（GB/T 14954-1994)
化学成分：
Cu:59.0-61.0
Sn:1.0-1.5
Ni:0.5
Fe:0.10
Pb:0.30
Zn:余量
杂质1.0
力学性能：
抗拉强度（σb/MPa）：≥315伸长率δ10 (%)：≥15
注：除制锁、钟用线材外的其他线材的室温拉伸力学性能试样尺寸：直径0.05～2.0●热处理规范：热加工温度760～800℃;退火温度550～650℃。

特性及适用范围：
性能与HSn62-1相近，比较好的热加工性能，可焊性能.耐蚀性能和冷加工性能好，主要产品为线材
上海商虎。

ab c d金属材料-型材Metal Material – Sectionmaterial TA012-002 A1/ 81范围/Scope：本标准适用于公司内自行设计的水轮机组及其它产品和工装的设计。

This standard is applicable to the design of TAH made hydro-turbine unit, other product and template.本标准作为设计选用材料的主要依据。

This standard shall be the basis of material selection for design.当本标准中的型材不能满足设计和加工及工装的材料选择时而选用标准以外的型材时，必须经过部门负责人的同意方可进行。

Once the selected section material is out of scope of this standard, the selection of relative material should be approved by department supervisor.2引用标准/reference standard编制：王金娥Prepared by: WANG JINE 校核：杨洁春Checked by: YANG JIECHUN批准：大卫.谢波Approved by: DT Shepperd部门：水机部Department: TE 日期: 2001.11.15Date:备注：Observation:GB/T 702-1986热轧圆钢和方钢尺寸、外形、重量及允许偏差Hot-Rolled Round And Square Steels —Dimension，Shape，Weight And ToleranceGB/T 704-1988热轧扁钢尺寸、外形、重量及允许偏差Dimensions，Shape，Weight And Tolerances For Hot-Rolled FlatsGB/T 706-1988热轧工字钢尺寸、外形、重量及允许偏差Hot-Rolled beam steel — Dimensions, Shape, Weight AndToleranceGB/T 707-1988热轧槽钢尺寸、外形、重量及允许偏差Hot-Rolled Channel Steel — Dimension, Shape, WeightAnd TolerancesGB/T 711-1988优质碳素结构钢热轧厚钢板和宽钢带Hot-Rolled Quality Carbon Structural Steel Plates AndWedgeGB/T 905-1994冷拉圆钢、方钢、六角钢尺寸、外形、重量及允许偏差Dimension, Shape, Weight And Tolerance For Cold-DrawnRound, Square And Hexagonal SteelsGB/T 3078-1994优质碳素结构钢冷拉钢材技术条件Technical Requirements For Quality Structural Steel ColdDrawn BarsGB/T 3091-1993低压流体输送用镀锌焊接钢管Pipe For Galvanized Welded steel Low Pressure Service GB/T 3092-1993低压流体输送用焊接钢管Welded Steel Pipe For Low Pressure Service2/8TA012-002 AGB/T 3274-1988碳素结构钢和低合金结构钢 热轧厚钢板和钢带Carbon Structural And low Alloy Steel – Rotled Plates AndStripsGB/T 3277-1991花纹钢板Corrugated Steel Plates With Lath And LentilformGB/T 4237-1992不锈钢热轧钢板Hot Rolled Stainless Steel Sheets And PlatesGB/T 8162-1999结构用无缝钢管Seamless Steel Tubes For Structural PurposesGB/T 8163-1999输送流体用无缝钢管Seamless Steel Tubes For Liquid ServiceGB/T 9787-1988热轧等边角钢 尺寸、外形、重量及允许偏差Hot-Rolled Equal-Leg Angle Steel—Dimensions,Shape,Weight And TolerancesGB/T 9788-1988热轧不等边角钢 尺寸、外形、重量及允许偏差Hot-Rolled Unequal-Leg Angle Steel—Dimensions,Shape,Weight And TolerancesGB/T 12770-1991机械结构用不锈钢焊接钢管Welded Stainless Steel Tubes For Machine StructureGB/T 14976-1994流体输送用不锈钢无缝钢管Stainless Steel Seamless Pipes For Fluid TransportGB/T 17395-1998无缝钢管尺寸、外形、重量及允许偏差Dimensions, Shapes, Masses And Tolerances Of SeamlessSteel Tubes3 本标准的使用/Usage of this standard3.1提采购时，必须将所选型材的标准给出，以避免出现采购错误。