2N956中文资料
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ASTM钢铁标准.A956
NOTE 1—The original title of this standard was “Standard Test Method for Equotip Hardness Testing of Steel Products”.1
(generated by a spring force) onto a surface of the material under test. The ratio of the rebound velocity to the impact velocity of the impact body is a measure of the hardness of the material under test. 3.1.4 surface finish—all references to surface finish in this test method are defined as surface roughness (that is, Ra = average roughness value, AA = arithmetic average). 3.1.5 verification—checking or testing the instrument to ensure conformance with this test method. 4. Significance and Use 4.1 Hardness of a material is a poorly defined term that may have many meanings depending on the type of test performed and the expectations of the person involved. The Leeb hardness test is of the dynamic or rebound type, which primarily depends both on the plastic and on the elastic properties of the material being tested. The results obtained are indicative of the strength and dependent on the heat treatment of the material tested. 4.2 The Leeb hardness test is a superficial determination only measuring the condition of the surface contacted. The results generated at that location do not represent the part at any other surface location and yield no information about the material at subsurface locations. A. GENERAL DESCRIPTION OF INSTRUMENTS AND TEST PROCEDURE FOR LEEB HARDNESS TEST 5. Apparatus 5.1 The instrument used for Leeb hardness testing consists of (1) an impact device that is equipped with a tungsten carbide ball or synthetic diamond tipped impact body, an induction coil velocity measuring assembly, and a support ring, and ( 2) an electronic digital display hardness indicating device. 5.2 Impact Devices—There are six types of impact devices used in Leeb hardness testing. These are the D, DC, D+15, G, C, and the E impact units. Brief descriptions of the types of devices and their common applications are given in Appendix X1. 5.3 Summary of Test Method—During a hardness test, an impact body with a spherically shaped tungsten carbide or diamond tip impacts under spring force, the test surface from which it rebounds. The impact and rebound velocities are
(generated by a spring force) onto a surface of the material under test. The ratio of the rebound velocity to the impact velocity of the impact body is a measure of the hardness of the material under test. 3.1.4 surface finish—all references to surface finish in this test method are defined as surface roughness (that is, Ra = average roughness value, AA = arithmetic average). 3.1.5 verification—checking or testing the instrument to ensure conformance with this test method. 4. Significance and Use 4.1 Hardness of a material is a poorly defined term that may have many meanings depending on the type of test performed and the expectations of the person involved. The Leeb hardness test is of the dynamic or rebound type, which primarily depends both on the plastic and on the elastic properties of the material being tested. The results obtained are indicative of the strength and dependent on the heat treatment of the material tested. 4.2 The Leeb hardness test is a superficial determination only measuring the condition of the surface contacted. The results generated at that location do not represent the part at any other surface location and yield no information about the material at subsurface locations. A. GENERAL DESCRIPTION OF INSTRUMENTS AND TEST PROCEDURE FOR LEEB HARDNESS TEST 5. Apparatus 5.1 The instrument used for Leeb hardness testing consists of (1) an impact device that is equipped with a tungsten carbide ball or synthetic diamond tipped impact body, an induction coil velocity measuring assembly, and a support ring, and ( 2) an electronic digital display hardness indicating device. 5.2 Impact Devices—There are six types of impact devices used in Leeb hardness testing. These are the D, DC, D+15, G, C, and the E impact units. Brief descriptions of the types of devices and their common applications are given in Appendix X1. 5.3 Summary of Test Method—During a hardness test, an impact body with a spherically shaped tungsten carbide or diamond tip impacts under spring force, the test surface from which it rebounds. The impact and rebound velocities are
2SA966资料
TOSHIBA Transistor Silicon PNP Epitaxial Type (PCT Process)2SA966Audio Power Amplifier Applications• Complementary to 2SC2236 and 3-W output applications.Absolute Maximum Ratings (Ta = 25°C)Characteristics Symbol Rating UnitCollector-base voltage V CBO −30 V Collector-emitter voltage V CEO −30 V Emitter-base voltage V EBO −5 V Collector current I C−1.5 AEmitter currentI E 1.5 A Collector power dissipation P C 900 mW Junction temperature T j 150 °C Storage temperature rangeT stg−55 to 150°CNote: Using continuously under heavy loads (e.g. the application of high temperature/current/voltage and the significant change in temperature, etc.) may cause this product to decrease in thereliability significantly even if the operating conditions (i.e. operating temperature/current/voltage, etc.) are within the absolute maximum ratings.Please design the appropriate reliability upon reviewing the Toshiba Semiconductor Reliability Handbook (“HandlingPrecautions”/Derating Concept and Methods) and individual reliability data (i.e. reliability test report and estimated failure rate, etc).Unit: mmJEDEC TO-92MOD JEITA ―TOSHIBA 2-5J1A Weight: 0.36 g (typ.)Electrical Characteristics (Ta = 25°C)Characteristics Symbol TestCondition MinTyp.Max UnitCollector cut-off current I CBO V CB = −30 V, I E = 0 ――−100nAEmitter cut-off current I EBO V EB = −5 V, I C = 0 ――−100nA Collector-emitter breakdown voltage V (BR) CEO I C = −10 mA, I B = 0 −30 ―― V Emitter-base breakdown voltage V (BR) EBO I E = −1 mA, I C = 0 −5 ―― VDC current gain h FE(Note)V CE = −2 V, I C = −500 mA 100 ― 320Collector-emitter saturation voltage V CE (sat)I C = −1.5 A, I B = −0.03 A ――−2.0V Base-emitter voltage V BE V CE = −2 V, I C = −500 mA ――−1.0V Transition frequency f T V CE = −2 V, I C = −500 mA ― 120 ― MHz Collector output capacitance C ob V CB = −10 V, I E = 0, f = 1 MHz ― 40 ― pF Note: h FE classification O: 100 to 200, Y: 160 to 320Markinglead (Pb)-free package orlead (Pb)-free finish.indicatorCollector current I C (mA)h FE – ICD C c u r re n t g a i n h F ECollector current I C (mA)V CE (sat) – I CC o l l e c t o r -e m i t t e r s a t u r a t i on v o l t a g eV C E (s a t ) (V )Base-emitter voltage V BE (V)I C – V BEC oll e c t o rc u r r e n t I C (m A )Ambient temperature Ta (°C)P C – TaC o l l e c t o r p owe r d i s s ip a t io n P C (W )Collector-emitter voltage V CE (V)Safe Operating AreaC o l l e c t o r c u r r e n t I C (A )1.00 0 20 40 60 80 100 120 140 160 1800.20.40.60.8−−−−−−−−−−−−−−−−−−Collector-emitter voltage V CE (V)I C – V CEC o l l e c t o r c u r r e n t I C (m A )−−−−−−−−−−−−−−−−−RESTRICTIONS ON PRODUCT USE20070701-EN •The information contained herein is subject to change without notice.•TOSHIBA is continually working to improve the quality and reliability of its products. Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such TOSHIBA products could cause loss of human life, bodily injury or damage to property.In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as set forth in the most recent TOSHIBA products specifications. Also, please keep in mind the precautions and conditions set forth in the “Handling Guide for Semiconductor Devices,” or “TOSHIBA Semiconductor Reliability Handbook” etc.• The TOSHIBA products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.).These TOSHIBA products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury (“Unintended Usage”). Unintended Usage include atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical instruments, all types of safety devices, etc.. Unintended Usage of TOSHIBA products listed in his document shall be made at the customer’s own risk.•The products described in this document shall not be used or embedded to any downstream products of which manufacture, use and/or sale are prohibited under any applicable laws and regulations.• The information contained herein is presented only as a guide for the applications of our products. No responsibility is assumed by TOSHIBA for any infringements of patents or other rights of the third parties which may result from its use. No license is granted by implication or otherwise under any patents or other rights of TOSHIBA or the third parties.• Please contact your sales representative for product-by-product details in this document regarding RoHS compatibility. Please use these products in this document in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled substances. Toshiba assumes no liability for damage or losses occurring as a result of noncompliance with applicable laws and regulations.。
TL956 中文版
切换间隙,参见第 5.8 节,切换间隙 1 时间(分钟)
5
“b”
10
“c”
15
图 1---喷水循环 实验过程 保护程度 IP X 4K
参见 PV 3501 参见 PV 3501
喷水循环
实验后,在室温及负载 13.5v 电压的情况下点亮 15 分钟 ,不可以有看得见的水。
5.3 对白炽灯座的机械要求
5.3.1 机械功能测试 要求 a) VW751 20
耐久性测试
见第 5.10 节
防水溅测试
见第 5.2 节
湿度测试
见第 5.12 节
疲劳极限测试
见第 5.5 节 a) b)
对灯罩的要求
见第 5.4 节
防腐测试
见第 5.8 节 b1)
对白炽灯座的要求
见第 5.3 节
防尘测试
见第 5.11 节
4.1.1.2 牌照灯
光度测量试验
见表 1
密封测试
见第 5.1 节
b) VW751 22 白炽灯样品参见 VW 1962 20
5.3.2 白炽灯在灯座上的稳定性 参见 VW 751 22
5.3.3 接触压力 5.3.4 插头的挤压强度和断开力 5.4 对灯罩的要求
5 到 20N 参见 VW 801 06
5.4.1 外观 无缝隙和表面无缺陷
5.4.2 材质
参见 TL 591
机械循环空气中的老化测试,空载
见第 5.6 节 a)
机械循环空气中的老化测试,有负载
见第 5.7 节 a)
耐久性测试
见第 5.10 节
防水溅测试
见第 5.2 节
湿度测试
见第 5.12 节
疲劳极限测试
2N1595中文资料
2N1595 thru 2N1599SILICON THYRISTORIndustrial-type, low-current silicon controlled rectifiersin a three-lead package ideal for printed-circuit applications.Current handling capability of 1.6 amperes at junction temperetures to 125°CMAXIMUM RATINGS (*)T J=125°C unless otherwise notedSymbol Ratings2N15952N15962N15972N15982N1599V RSM(REP)Peak reverse blocking voltage *50100200300400VI T(RMS)Forward Current RMS (all conduction1.6Ampangles)I TSM Peak Surge Current15Amp (One Cycle, 60Hz, T J=-65 to +125°C)P GM Peak Gate Power – Forward0.1W P G(AV)Average Gate Power - Forward0.01W I GM Peak Gate Current – Forward0.1Amp V GFM Peak Gate Voltage - Forward10V V GRM Peak Gate Voltage - Reverse10V T J Operating Junction Temperature-65 to +125Range°C T STG Storage Temperature Range-65 to +150ELECTRICAL CHARACTERISTICST J=25°C unless otherwise noted, R GK=1000ΩSymbol Ratings2N15952N15962N15972N15982N1599V DRM Peak Forward BlockingMin :50100200300400V Voltage *I RRM Peak Reverse Blocking CurrentMax : 1.0mA (Rated V DRM, T J =125°C)2N1595 thru 2N1599Symbol Ratings2N15952N15962N15972N15982N1599I DRM Peak Forward Blocking Current(Rated V DRM with gate open , T J=125°C)Max :1.0mAI GT Gate Trigger Current (2)Anode Voltage=7.0 Vdc, R L=12ΩTyp : 2.0Max : 10mAGate Trigger VoltageAnode Voltage=7.0 Vdc, R L=12ΩTyp : 0.7Max : 3.0V GTV DRM= Rated, R L=100Ω, T J=125°C Min : 0.2VI H Holding CurrentAnode Voltage=7.0 Vdc, gate open Typ : 5.0mAV TM Forward On VoltageI T=1 AdcTyp : 1.1Max : 2.0Vt gt Turn-On Time (t d+t r)I GT=10 mA, I T=1 A Typ : 0.8µst q Turn-Off TimeI T=1 A, I R =1 A, dv/dt=20 V/µs,T J=125°CV DRM= Rated VoltageTyp : 10µs* V DRM or V RSM can be applied for all types on a continuous dc basis without incurring damage. MECHANICAL DATA CASE TO-39DIMENSIONSmm inchesA6,250,24B13,590,53C9,240,36D8,240,32E0,780,03F1,050,041G0,420,165H45°L5,10,2Pin 1 :CathodePin 2 :GatePin 3 :AnodeInformation furnished is believed to be accurate and reliable. However, CS assumes no responsability for the consequences of use of such information nor for errors that could appear.Data are subject to change without notice.。
2N2369中文资料
ft
VCE=10V,IC=10mA, f=100MHz
Output Capacitance
Cobo
VCB=5V, IE=0, f=140kHz
2N2369/2369A
2N2369 2N2369A UNIT
-
40-120
-
>30
-
>20
>20
-
>500 <4.0
>500 <4.0
MHZ pF
Turn on Time Turn off Time
40-120 -
>20
UNIT V V V V nA uA nA nA V V V V V V V V V
page : 1
元器件交易网
ELECTRICAL CHARACTERISTICS (Ta=25 deg C Unless Otherwise Specified)
DESCRIPTION
SYMBOL TEST CONDITION
2N2369
Collector -Emitter Voltage
VCEO*(sus)IC=10mA, IB=0
>15
Collector -Emitter Voltage
VCES
IC=10uA, VBE=0
>40
Collector -Base Voltage
Base Emitter Saturation Voltage
VBE(Sat) * IC=10mA,IB=1mA
0.7-0.85
IC=30mA,IB=3mA
-
IC=100mA,IB=10mA
-
IC=10mA,IB=1mA,Ta= +125 deg C -
2N5609中文资料
TO-66
Electrical Characteristics Tc=25
SYMBOL ICBO IEBO ICEO VCBO V(BR)CEO VEBO VCEsat-1 VCEsat-2 VCEsat-3 VCEsat-4 hFE-1 hFE-2 hFE-3 hFE-4 VBE(sat)1 VBE(sat)2 VBE(sat)3 fT tf ts PARAMETER Collector-base cut-off current Emitter-base cut-off current Collector-emitter cut-off current Collector-base breakdown voltage Collector-emitter breakdown voltage Emitter-base breakdown voltage Collector-emitter saturation voltages Collector-emitter saturation voltages Collector-emitter saturation voltages Collector-emitter saturation voltages Forward current transfer ratio Forward current transfer ratio Forward current transfer ratio Forward current transfer ratio Base-emitter saturation voltages Base-emitter saturation voltages Base-emitter saturation voltages Transition frequency at f = 1MHz Fall time Tum-off storage time IC=1A,VCE=2V 1.0 V IC=2.5A,VCE=5V 70 200 IC =1A; IB =0.1A 0.5 V IC=10mA,IB=0 80 V CONDITIONS VCB =80V;IE=0 VEB =5V, IC=0 MIN MAX 10 10 UNIT A A
2N3906中文资料(nte)中文数据手册「EasyDatasheet - 矽搜」
VCE = 1V, I C = 1mA
40 − − 80 − −
2N3905 2N3906
VCE = 1V, I C = 10mA
50 − 150 100 − 300
2N3905 2N3906
VCE = 1V, I C = 50mA
30 − − 60 − −
2N3905 2N3906
VCE = 1V, I C = 100mA
芯片中文手册,看全文,戳
2N3905 & 2N3906 硅PNP晶体管
一般用途
TO92类型封装
绝对最大额定值:
集电极 - 发射极电压,V
CEO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40V
器件总功耗(T
C = +255C), PD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.5W
减免上述255℃. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12MW / 5C
减免上述255℃. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.0MW / 5C
器件总功耗(T
2N5566中文资料
Unit
V mA pA nA pA nA W V
mS mS mS
pF nV⁄ √Hz dB
mV mV/ _C
dB NCBD
8-2
Document Number: 70254 S-04031—Rev. D, 04-Jun-01
元器件交易网
2N5564/5565/5566
元器件交易网
2N5564/5565/5566
Vishay Siliconix
Matched N-Channel JFET Pairs
PRODUCT SUMMARY
Part Number
2N5564 2N5565 2N5566
VGS(off) (V)
–0.5 to –3 –0.5 to –3 –0.5 to –3
76
Notes a. Typical values are for DESIGN AID ONLY, not guaranteed nor subject to production testing.
b. Pulse test: PW v300 ms duty cycle v3%. c. This parameter not registered with JEDEC.
160
0 –10
rDS(on) – Drain-Source On-Resistance ( W )
120 VGS(off) = –2 V
80
40
gfs – Forward Transconductance (mS)
0 –55 –35 –15 5
APPLICATIONS
D Wideband Differential Amps D High-Speed,
2N5109中文资料(Central Semiconductor)中文数据手册「EasyDatasheet - 矽搜」
功率耗散(TC = 75°C)
工作和存储结温
符号
VCBO VCEO VEBO
IC IB PD PD TJ, Tstg
电气特性: 符号
ICEV ICEV ICEO IEBO BVCBO BVCER BVCEO VCE(SAT) hFE hFE fT Cob NF GPE
测试条件
VCE=35V, VBE=1.5V
5.0
VCE=15V, IC=50mA, f=200MHz
1200
VCB=15V, IE=0, f=1.0MHz
VCE=15V, IC=10mA, f=200MHz
VCE=15V, IC=50mA, f=200MHz
11
40 20 3.0 400 400 1.0 2.5 -65到+200
TYP
MAX
5.0
5.0
20
100
0.5 210
3.5 3.0
UNITS V V V mA mA W W °C
UNITS mA mA μA μA V V V V
MHz pF dB dB
R4 (7-June 2109
硅
NPN晶体管 RF
TO-39 CASE - 机械外形
前导码:
1)发射 2)基 3)集电极
标记:全部型号
R4 (7-June 2011)
(TA = 25°C除非另有说明) MIN
VCE=15V, VBE=1.5V, TC=150°C
VCE=15V
VEB=3.0V
IC=0.1mA
40
IC=5.0mA, RBE=10Ω
40
IC=5.0mA
20
IC=100mA, IB=10mA
工作和存储结温
符号
VCBO VCEO VEBO
IC IB PD PD TJ, Tstg
电气特性: 符号
ICEV ICEV ICEO IEBO BVCBO BVCER BVCEO VCE(SAT) hFE hFE fT Cob NF GPE
测试条件
VCE=35V, VBE=1.5V
5.0
VCE=15V, IC=50mA, f=200MHz
1200
VCB=15V, IE=0, f=1.0MHz
VCE=15V, IC=10mA, f=200MHz
VCE=15V, IC=50mA, f=200MHz
11
40 20 3.0 400 400 1.0 2.5 -65到+200
TYP
MAX
5.0
5.0
20
100
0.5 210
3.5 3.0
UNITS V V V mA mA W W °C
UNITS mA mA μA μA V V V V
MHz pF dB dB
R4 (7-June 2109
硅
NPN晶体管 RF
TO-39 CASE - 机械外形
前导码:
1)发射 2)基 3)集电极
标记:全部型号
R4 (7-June 2011)
(TA = 25°C除非另有说明) MIN
VCE=15V, VBE=1.5V, TC=150°C
VCE=15V
VEB=3.0V
IC=0.1mA
40
IC=5.0mA, RBE=10Ω
40
IC=5.0mA
20
IC=100mA, IB=10mA
TL956 中文版
见表 1
密封测试
见第 5.1 节
机械循环空气中的老化测试,空载
见第 5.6 节
防水溅测试
见第 5.2 节
机械循环空气中的老化测试,有负载
见第 5.7 节
耐久性测试
见第 5.10 节
疲劳极限测试
见第 5.5 节
对灯罩的要求
见第 5.4 节
防腐测试
见第 5.8 节
壳体撞击测试
见第 5.13 节
过电压保护测试
耐久性测试
见第 5.10 节
防水溅测试
见第 5.2 节
湿度测试
见第 5.12 节
疲劳极限测试
见第 5.5 节 a) b)
对灯罩的要求
见第 5.4 节
防腐测试
见第 5.8 节 b1)
对白炽灯座的要求
见第 5.3 节
防尘测试
见第 5.11 节
4.1.1.2 牌照灯
光度测量试验
见表 1
密封测试
见第 5.1 节
见第 5.10 节
壳体撞击测试
见第 5.13 节
粘结强度
见第 5.14 节
过电压保护测试
见第 5.16 节
5 对试验的说明 5.1 密封 以 30mbar 的过压对试样加载,这样可以检验焊缝和粘连缝的密封性(外部照明灯结构上通 风的所有开口必须封闭)。焊缝和粘连缝不能在测试启动时受到机械的强压。 用中心连接头施压。 把试样浸入水中大约 15 秒钟(焊缝和粘连缝及密封垫浸入水中的深度:水面下 50mm),这 时不可以出现气泡。 5.2 防水溅保护
切换间隙,参见第 5.8 节,切换间隙 1 时间(分钟)
5
“b”
10
“c”
常林956装载机简介
常林956装载机简介(整机单价人民币33万)常林956装载机是在ZL50G-3的基础上听取了港口、码头、煤矿、采石场等用户意见和建议的基础上,针对恶劣工况要求而设计的5吨加强型装载机,对液压操纵系统、转向系统以及传动系统进行了改进。
并实现了六大突破、十八项技术升级,956将是常林5吨装载机主导产品之一。
常林装载机1997年荣获中国机械工业名牌产品2004/2007年装载机荣获中国名牌产品续二十一年被中质协评为“用户满意产品”1984、1990年唯一两次荣获国家优质产品银质奖(装载机行业最高奖)一.实现六大突破第一大突破:更强956牵引力大幅度提升,达到150KN,掘起力显著提升达到165KN,提升能力显著提高。
保证满足高强度的作业,适应各种恶劣工况的能力更出众。
第二大突破:更高卸载高度3100 mm,卸载距离更远,满足更高作业需求,加长臂能够达到3400mm(工作装置:13R),3610mm(工作装置:13S);第三大突破:更可靠整车管路接头采用双重密封结构,有效解决常见渗漏难题;全新设计散热系统,满足高温环境重载要求;第四大突破:更舒适与专业汽车设计公司合作,驾驶室内饰豪华,密封性更好,隔音效果更强。
第五大突破:更节能铲掘力的大幅度提高和铲装效率的大幅度提升,大大降低作业时的无效消耗;变矩效率提高到82%,节省更多的燃油。
第六大突破:全功能型既能满足重载作业(一档作业),也能适合铲装松散物料(二档作业)。
二.十八项技术升级:1、优化传动系统:全面优化设计新型变矩器,变矩效率高达82%,吸收功率性能好;优化传动系统速比,从而牵引力得到明显提升(一档150kN,增加15%;二档90N,增加28%),适应重载及高效不同要求工况,变速箱内输入输出油封采用进口件。
2、工作装置全新设计:提升能力显著增加(在系统压力降10%条件下,由原来的20Mpa降为18Mpa,压力的降低带来了减低诸多问题出现的可能性,同时地面提升力仍有10%的提高),标准臂的卸载高度达3100mm,机构实现自动放平功能,斗形更合理,装满系数提高。
2N2906中文资料
MIN. MAX. UNIT
−
−60
V
−
−40
V
−
−60
V
−
−5
V
−
−600 mA
−
−800 mA
−
−200 mA
−
400
mW
−
1.2
W
−65
+150 °C
−
200
°C
−65
+150 °C
VALUE 438 146
UNIT K/W K/W
1997 Jun 02
3
Philips Semiconductors
DC current gain 2N2906A
collector-emitter saturation voltage base-emitter saturation voltage collector capacitance emitter capacitance transition frequency
PNP switching transistors
Product specification
2N2906; 2N2906A
CHARACTERISTICS Tamb = 25 °C unless otherwise specified
SYMBOL
PARAMETER
CONDITIONS
MIN. MAX. UNIT
2N2906 2N2906A emitter-base voltage collector current (DC) peak collector current peak base current total power dissipation
2N6796中文资料
Min.
100
Typ.
Max. Unit
V 250 1000 100 –100 µA
VDS=Rated VDSS
nA
ON CHARACTERISTICS
Gate Thresshold Voltage Static Drain–Source On–Resistance Drain–Source On–Voltage Forward Transconductance 2.0 4.0 0.18 0.35 1.56 3.0 350 150 50 9.0. 900 500 150 30 VDD = 30V ID = 5.0A 75 40 45 0.75 1.5
Prelim. 11/98
Underside View PIN 1 – Source PIN 2 – Gate PIN 3 – Drain Case
ABSOLUTE MAXIMUM RATINGS (Tcase = 25°C unless otherwise stated)
Drain–Source Voltage VDGR Drain–Gate Voltage (RGS = 1.0mΩ) VGS Gate–Source Voltage ID Drain Current Continuous IDM Drain Current Pulsed PD Total Device Dissipation @ TC = 25°C Derate above 25°C TJ , TSTG Operating and Storage Junction Temperature Range THERMAL CHARACTERISTICS RθJC Thermal Resistance Junction to Case RθJC Thermal Resistance Junction to Ambient TL Maximum Lead Temperature 1.5mm from Case for 10 s VDSS 100V 100V ±20V 8.0A 32A 25W 0.2W/ °CW –55 to +150°C 5.0°CW 175°CW 300°C
SEN-R-956-026中文资料
TECHNICAL DATA SHEET 4200…SURFACE MOUNT DIE WITH HEAT ABSORBING STANDOFF TERMINAL STRIPS TRANSIENT VOLTAGE SUPPRESSOR 500 WATT SERIES Glass Passivated Die Plus Dual Heat StripsFeatures:• Low Profile• Broad Voltage Range Available - - 6.8 to 200 Volts • Broad Spectrum Transient Suppression• Rapid Response - - 4 nanoseconds typical• Built-in Heat Absorbing Terminations• Electrically Similar to Mil-Prf-19500/516 Applications:• Connector I/O Surge Suppression• Data Line Protection Description: This is a bipolar transient voltage suppressor series extending from 6.8 volts to 200 volts intended for surface mount applications.Each device comes as a “Cell” with its own heat absorbing terminals pre-bonded at high temperature. This permits mounting on printed circuit boards that cannot provide their own heat sinking. Each terminal is silver plated and is solderable permitting solder down attachment with a very small footprint. Each unit is bi-symmetrical so any orientation can be used.ELECTRICAL CHARACTERISTICSPARAMETER SYMBOL Test Conditions Min TYP Max.Units Response Turn-on Time ton 2 5 nsTransient Energy Pulse (Cell) Ep 1 10uS rise, I= 0.5Ip at t=100us (exponentialdecay)1500 WTransient Energy Pulse (Cell) Ep 2 10uS rise, I= 0.5Ip at t=1.0mS (exponentialdecay)500 WTransient Energy Pulse (Cell) Ep 3 10uS rise, I= 0.5Ip at t=10mS (exponentialdecay)150 WTransient Energy Pulse (Cell) Ep 4 10uS rise, I= 0.5Ip at t=50mS (exponentialdecay)70 WTransient Energy Pulse(Cell)Ep 5 10uS rise, I= 0.5Ip at t=50mS (step pulse) 50 W Electrical Parameters See TableMaximum SolderTemperatureTmax 10 second exposure 300 ºC Thermal Resistance (J-C) ΤJC Assume heat sink on terminal strip ends 18 30 ºC/WNote 1: “Die Only” configuration requires user to provide adequate energy absorption. Note 2: Terminal strips are 0.009” to 0.011” thick copper with nickel and silver plate.0.034"0.039"Typ0.052"0.056"0.0115"0.0155"Bipolar Die OnlySEN-R-956-XXX 500Watt TVS SeriesNominal Vz min Vz max TC (nom) Ir max Part Vz Iz @ Iz @ Iz of Vz Vr @ Vr Vcc Ip Number (V) (mA) (V) (V) (%.°C) (V) (uA) (V) (A) SEN-R-956-001 6.8 10 6.40 7.25 0.050 5.0 1600 9.2 54.3 SEN-R-956-002 7.2 10 6.67 7.67 0.060 6.0 1600 10.3 48.5 SEN-R-956-003 7.8 10 7.22 8.30 0.060 6.5 1000 11.2 44.6 SEN-R-956-004 8.4 10 7.78 8.95 0.060 7.0 400 12.0 41.7 SEN-R-956-005 9.0 1 8.33 9.58 0.070 7.5 200 12.9 38.8 SEN-R-956-006 9.6 1 8.89 10.23 0.070 8.0 100 13.6 36.8 SEN-R-956-007 10 1 9.44 10.82 0.070 8.5 20 14.4 34.7 SEN-R-956-008 11 1 10.00 11.50 0.080 9.0 10 15.4 32.5 SEN-R-956-009 12 1 11.10 12.80 0.080 10.0 5 17.0 29.4 SEN-R-956-010 13 1 12.20 14.00 0.080 11.0 5 18.2 27.5 SEN-R-956-011 14 1 13.30 15.50 0.085 12.0 5 19.9 25.1 SEN-R-956-012 15 1 14.40 16.50 0.085 13.0 5 21.5 23.3 SEN-R-956-013 17 1 15.60 17.90 0.085 14.0 5 23.2 21.6 SEN-R-956-014 18 1 16.70 19.20 0.090 15.0 5 24.4 20.5 SEN-R-956-015 19 1 17.80 20.50 0.090 16.0 5 26.0 19.2 SEN-R-956-016 20 1 18.90 21.70 0.090 17.0 5 27.6 18.1 SEN-R-956-017 22 1 20.00 23.30 0.095 18.0 5 29.2 17.1 SEN-R-956-018 24 1 22.20 25.50 0.095 20.0 5 32.4 15.4 SEN-R-956-019 26 1 24.40 28.00 0.095 22.0 5 35.5 14.1 SEN-R-956-020 29 1 26.70 30.70 0.095 24.0 5 38.9 12.9 SEN-R-956-021 31 1 28.90 33.20 0.095 26.0 5 42.1 11.9 SEN-R-956-022 33 1 31.10 35.80 0.095 28.0 5 45.4 11.0 SEN-R-956-023 36 1 33.30 38.30 0.095 30.0 5 48.4 10.3 SEN-R-956-024 39 1 36.70 42.20 0.100 33.0 5 53.3 9.4 SEN-R-956-025 43 1 40.00 46.00 0.100 36.0 5 58.1 8.6 SEN-R-956-026 48 1 44.40 51.10 0.100 40.0 5 64.5 7.8 SEN-R-956-027 51 1 47.80 54.90 0.100 43.0 5 69.4 7.2 SEN-R-956-028 54 1 50.00 57.50 0.100 45.0 5 72.7 6.9 SEN-R-956-029 57 1 53.30 61.30 0.100 48.0 5 77.4 6.5 SEN-R-956-030 61 1 56.7 65.2 0.100 51.0 5 82.4 6.1 SEN-R-956-031 65 1 60.0 69.0 0.100 54.0 5 87.1 5.7 SEN-R-956-032 69 1 64.4 74.1 0.105 58.0 5 93.6 5.3 SEN-R-956-033 72 1 66.7 76.7 0.105 60.0 5 96.8 5.2 SEN-R-956-034 76 1 71.1 81.8 0.105 64.0 5 103.0 4.9 SEN-R-956-035 84 1 77.8 89.5 0.110 70.0 5 113.0 4.4 SEN-R-956-036 90 1 83.3 95.8 0.110 75.0 5 121.0 4.1 SEN-R-956-037 93 1 86.7 99.7 0.110 78.0 5 126.0 4.0 SEN-R-956-038 101 1 94.4 108.2 0.110 85.0 5 137.0 3.6 SEN-R-956-039 108 1 100.0 115.5 0.110 90.0 5 146.0 3.4 SEN-R-956-040 120 1 111.0 128.0 0.110 100.0 5 162.0 3.1 SEN-R-956-041 131 1 122.0 140.5 0.110 110.0 5 177.0 2.8 SEN-R-956-042 143 1 133.0 153.0 0.110 120.0 5 193.0 2.6 SEN-R-956-043 155 1 144.0 165.5 0.110 130.0 5 209.0 2.4 SEN-R-956-044 180 1 167.0 192.5 0.110 150.0 5 243.0 2.1 SEN-R-956-045 192 1 178.0 205.0 0.110 160.0 5 259.0 1.9 SEN-R-956-046 203 1 189.0 217.5 0.110 170.0 5 275.0 1.81Time (s)Clamp Power vs Time for Sensitron 500W TVS SeriesTime (mS)Exponential Decay Pulse WaveformRated Vz of Device (V)Reverse Junction Capacitance for Sensitron 500W TVSSENSITRONSEMICONDUCTORTECHNICAL DATADISCLAIMER:1- The information given herein, including the specifications and dimensions, is subject to change without prior notice to improve product characteristics. Before ordering, purchasers are advised to contact the Sensitron Semiconductor sales department for the latest version of the datasheet(s).2- In cases where extremely high reliability is required (such as use in nuclear power control, aerospace and aviation, traffic equipment, medical equipment, and safety equipment), safety should be ensured by using semiconductor devices that feature assured safety or by means of users’ fail-safe precautions or other arrangement.3- In no event shall Sensitron Semiconductor be liable for any damages that may result from an accident or any other cause during operation of the user’s units according to the datasheet(s). Sensitron Semiconductor assumes no responsibility for any intellectual property claims or any other problems that may result from applications of information, products or circuits described in the datasheets.4- In no event shall Sensitron Semiconductor be liable for any failure in a semiconductor device or any secondary damage resulting from use at a value exceeding the absolute maximum rating.5- No license is granted by the datasheet(s) under any patents or other rights of any third party or Sensitron Semiconductor.6- The datasheet(s) may not be reproduced or duplicated, in any form, in whole or part, without the expressed written permission of Sensitron Semiconductor.7- The products (technologies) described in the datasheet(s) are not to be provided to any party whose purpose in their application will hinder maintenance of international peace and safety nor are they to be applied to that purpose by their direct purchasers or any third party. When exporting these products (technologies), the necessary procedures are to be taken in accordance with related laws and regulations.。
2N65中文资料
Resistance (Normailized) RDS(ON), Drain-to-Source On (Ω)
VDS, Drain-to-Source Voltage (V)
司 VGS, Gate-to-Source Voltage (V)
Fig3: Normalized On-Resistance Vs.Temperature
■Electronic Characteristics(TC=25℃)
PARAMETER
SYMBOL
TEST CONDITION
2N65 Series
N-Channel MOSFET
MIN
TYP
MAX
UNIT
Drain-source Breakdown Voltage
BVDSS
VGS=0V, ID=250μA
1.4
MAX 2.84
Thermal Resistance Junction-ambient
(Notes):
① (Repetitiv:e rating: Pulse width limited by maximum junction temperature)
)
② (Starting T =25 ℃ , V DD =50V, L=56mH, R G =25Ω, I AS =2A )
650
V
Breakdown Voltage Temperature Coefficient
ΔBVDSS/ΔTj
ID=250uA Referenced to 25℃
0.6
V/℃
Gate Threshold Voltage
VGS(TH)
VGS=VDS ID=250μA
2N6798中文资料
SOURCE DRAIN DIODE RATING CHARACTERISTICS
Diode Forward Voltage1 Continues Current Pulsed Current2 IF = IS dIF/DT = 100A/mS 150 Reverse Recovery Time Reverse Recovered Charge
VDS =0.8 x V(BR)DSS 0.25 2.5 3.0 600 250 80 8 42 12 30 IF = IS VGS = 0
mA W s(É)
pF
4.0
f = 1.0MHZ VDD = 77V ID = 3.5A
30 50 50 40 1.4 5.5 22 V A ns ns
RG = 7.5 ohms
Underside View PIN 1 – Source PIN 2 – Gate PIN 3 – Drain
ABSOLUTE MAXIMUM RATINGS (Tcase = 25°C unless otherwise stated)
VDS VGS ID Drain–Source Voltage Gate–Source Voltage Drain Current Continuous TC = 25°C TC = 100°C Drain Current Pulsed IDM IA Avalanche Current PD Total Device Dissipation @ TC = 25°C TC = 100°C TJ , TSTG Operating and Storage Junction Temperature Range THERMAL CHARACTERISTICS RqJC Thermal Resistance Junction to Case RqJC Thermal Resistance Junction to Ambient TL Maximum Lead Temperature 1.5mm from Case for 10 secs. 200V ±20V 5.5A 3.5A 22A 3.1A 25W 10W –55 to +150°C 5.0°CW 175°CW 300°C
常林936、956产品介绍
一、实现4大突破
突破
2
更强:牵引力大幅度提升,达到105KN,掘起力96KN,保 更强:牵引力大幅度提升,达到105KN,掘起力96KN, 105KN 96KN 证满足高强度的作业,适应各种恶劣工况的能力更出众。 证满足高强度的作业,适应各种恶劣工况的能力更出众。
一、4大突破
突破
3
更可靠:渗漏油质量攻关 ———— 6大改进措施 更可靠:
升级
热效率;前置、加大液压油散使散热效果更好;发动机风扇直
3
径加大更有利散热。 (2)变矩油温控制 变矩器效率提高使系统发热量降低;双变系统采用水冷式散热 器,冷却效果更好。
二、18项技术升级
双密封结构,有效解决常见渗漏难题: 双密封结构,有效解决常见渗漏难题: 管路接头采用(24°锥+O型圈密封)双密封结构形式,大大
一、实现6大突破
更强:牵引力大幅度提升,达到15吨,掘起力显著提升 更强:牵引力大幅度提升,达到15吨 15 达到16.5 16.5吨 提升能力显著提高。 达到16.5吨,提升能力显著提高。保证满足高强度的作 适应各种恶劣工况的能力更出众。 业,适应各种恶劣工况的能力更出众。
突破
1
一、实现6大突破
端面 槽+O 形圈
24° +O形圈, 24°锥+O形圈,双密封 形圈
二、10项技术升级
工作操纵、档位操纵采用软轴控制,操纵灵活、轻便、可靠;
升级
7
二、10项技术升级
单板车架结构设计,更利于空间布置,提高了维修性。
升级
8
二、10项技术升级
Hale Waihona Puke 提高灯具、反光镜的档次升级
9
二、10项技术升级
PC956说明书
NOTICEG The circuit application examples in this publication are provided to explain representative applications of SHARP devices and are not intended to guarantee any circuit design or license any intellectual property rights. SHARP takes no responsibility for any problems related to any intellectual property right of a third party resulting from the use of SHARP's devices.G Contact SHARP in order to obtain the latest device specification sheets before using any SHARP device. SHARP reserves the right to make changes in the specifications, characteristics, data, materials, structure, and other contents described herein at any time without notice in order to improve design or reliability. Manufacturing locations are also subject to change without notice.G Observe the following points when using any devices in this publication. SHARP takes no responsibility for damage caused by improper use of the devices which does not meet the conditions and absolute maximum ratings to be used specified in the relevant specification sheet nor meet the following conditions:(i)The devices in this publication are designed for use in general electronic equipment designs such as:--- Personal computers--- Office automation equipment--- Telecommunication equipment [terminal]--- Test and measurement equipment--- Industrial control--- Audio visual equipment--- Consumer electronics(ii)Measures such as fail-safe function and redundant design should be taken to ensure reliability and safety when SHARP devices are used for or in connection with equipment that requires higher reliability such as:--- Transportation control and safety equipment (i.e., aircraft, trains, automobiles, etc.)--- Traffic signals--- Gas leakage sensor breakers--- Alarm equipment--- Various safety devices, etc.(iii)SHARP devices shall not be used for or in connection with equipment that requires an extremely high level of reliability and safety such as:--- Space applications--- Telecommunication equipment [trunk lines]--- Nuclear power control equipment--- Medical and other life support equipment (e.g., scuba).G If the SHARP devices listed in this publication fall within the scope of strategic products described in the Foreign Exchange and Foreign Trade Law of Japan, it is necessary to obtain approval to export such SHARP devices.G This publication is the proprietary product of SHARP and is copyrighted, with all rights reserved. Under the copyright laws, no part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, for any purpose, in whole or in part, without the express written permission of SHARP. Express written permission is also required before any use of this publication may be made by a third party.G Contact and consult with a SHARP representative if there are any questions about the contents of this publication.。