丙烯酰：亚甲基双丙烯酰胺40%,371

NCE N-Channel Enhancement Mode Power MOSFETDescriptionThe NCE40H12 uses advanced trench technology and design to provide excellent R DS(ON) with low gate charge. It can be used in a wide variety of applications.General Features● V DS =40V,I D =120AR DS(ON) <4 m Ω @ V GS =10V R DS(ON) <7 m Ω @ V GS =4.5V● High density cell design for ultra low Rdson ● Fully characterized avalanche voltage and current ● Good stability and uniformity with high E AS ● Excellent package for good heat dissipation ● Special process technology for high ESD capabilityApplication● Load switching● Hard switched and high frequency circuits ● Uninterruptible power supply100% UIS TESTED!100% ∆Vds TESTED!Schematic diagramMarking and pin assignmentTO-220-3L top viewPackage Marking and Ordering InformationDevice MarkingDeviceDevice PackageReel SizeTape widthQuantityNCE40H12 NCE40H12 TO-220-3L-- -Absolute Maximum Ratings (T C =25℃unless otherwise noted)Parameter Symbol Limit UnitDrain-Source Voltage V DS 40 V Gate-Source Voltage V GS ±20 V Drain Current-ContinuousI D 120 ADrain Current-Continuous(T C =100℃) I D (100℃) 85 A Pulsed Drain Current I DM 330 A Maximum Power Dissipation P D 130 W Derating factor0.87 W/℃Single pulse avalanche energy (Note 5)E AS 1080 mJOperating Junction and Storage Temperature RangeT J ,T STG-55 To 175℃Thermal CharacteristicThermal Resistance,Junction-to-Case (Note 2)R θJC1.15/W ℃Electrical Characteristics (T C =25℃unless otherwise noted)ParameterSymbolCondition Min Typ Max UnitOff CharacteristicsDrain-Source Breakdown Voltage BV DSS V GS =0V I D =250μA 40 45 - V Zero Gate Voltage Drain Current I DSS V DS =40V,V GS =0V -- 1 μA Gate-Body Leakage Current I GSS V GS =±20V,V DS =0V - - ±100 nA On Characteristics (Note 3) Gate Threshold VoltageV GS(th) V DS =V GS ,I D =250μA 1.2 1.9 2.5 V V GS =10V, I D =20A - 3.2 4.0Drain-Source On-State Resistance R DS(ON) V GS =4.5V, I D=10A - 5.5 7.0 m ΩForward Transconductance g FSV DS =10V,I D =20A 26 - - SDynamic Characteristics (Note4) Input Capacitance C lss - 5400 - PF Output CapacitanceC oss - 970 - PFReverse Transfer Capacitance C rssV DS =20V,V GS =0V,F=1.0MHz- 380 - PF Switching Characteristics (Note 4) Turn-on Delay Time t d(on) - 15 - nSTurn-on Rise Time t r - 18 - nS Turn-Off Delay Time t d(off) - 52 - nSTurn-Off Fall Time t fV DD =20V,I D =2A,R L =1Ω V GS =10V,R G =3Ω - 23 - nSTotal Gate Charge Q g - 75 nCGate-Source Charge Q gs - 10.5 nCGate-Drain ChargeQ gd V DS =20V,I D =20A,V GS =10V- 17 nC Drain-Source Diode Characteristics Diode Forward Voltage (Note 3) V SDV GS =0V,I S =40A -1.2 V Diode Forward Current (Note 2)I S - - 120 A Reverse Recovery Time t rr - 42 - nS Reverse Recovery Charge Qrr TJ = 25°C, IF = 40Adi/dt = 100A/μs (Note3)- 45 - nCForward Turn-On Timet onIntrinsic turn-on time is negligible (turn-on is dominated by LS+LD)Notes:1. Repetitive Rating: Pulse width limited by maximum junction temperature.2. Surface Mounted on FR4 Board, t ≤ 10 sec.3. Pulse Test: Pulse Width ≤ 300μs, Duty Cycle ≤ 2%.4. Guaranteed by design, not subject to production5. E AS condition : Tj=25℃,V DD =20V,V G =10V,L=1mH,Rg=25Ω，I AS =46.5ANCE40H12Pb Free ProductTest circuit1) E ASTest Circuit2) Gate Charge Test Circuit3) Switch Time Test CircuitTypical Electrical and Thermal Characteristics (Curves)Vds Drain-Source Voltage (V)Figure 1 Output CharacteristicsVgs Gate-Source Voltage (V)Figure 2 Transfer CharacteristicsI D - Drain Current (A)Figure 3 Rdson- Drain CurrentT J -Junction Temperature(℃)Figure 4 Rdson-JunctionTemperatureQg Gate Charge (nC)Figure 5 Gate ChargeVsd Source-Drain Voltage (V)Figure 6 Source- Drain Diode ForwardR d s o n O n -R e s i s t a n c e (m Ω)I D - D r a i n C u r r e n t (A )I D - D r a i n C u r r e n t (A )N o r m a l i z e d O n -R e s i s t a n c eV g s G a t e -S o u r c e V o l t a g e (V )I s - R e v e r s e D r a i n C u r r e n t (A )Vds Drain-Source Voltage (V)Figure 7 Capacitance vs VdsVds Drain-Source Voltage (V)Figure 8 Safe Operation AreaT J -Junction Temperature (℃)Figure 9 Power De-ratingT J -Junction Temperature(℃)Figure 10 V GS(th) vs Junction TemperatureI D - D r a i n C u r r e n t (A )C C a p a c i t a n c e (p F )Square Wave Pluse Duration(sec)Figure 11 Normalized Maximum Transient Thermal Impedancer (t ),N o r m a l i z e d E f f e c t i v e T r a n s i e n t T h e r m a l I m p e d a n c eP o w e r D i s s i p a t i o n (W )TO-220-3L Package InformationDimensions In Millimeters Dimensions In Inches SymbolMin.Max.Min.Max.A 4.400 4.600 0.173 0.181A1 2.250 2.550 0.089 0.100b 0.710 0.910 0.028 0.036b1 1.170 1.370 0.046 0.054c 0.330 0.650 0.013 0.026c1 1.200 1.400 0.047 0.055D 9.910 10.250 0.390 0.404E 8.9500 9.750 0.352 0.384E1 12.650 12.950 0.498 0.510e 2.540 TYP. 0.100 TYP.e1 4.980 5.180 0.196 0.204F 2.650 2.950 0.104 0.116H 7.900 8.100 0.311 0.319h 0.000 0.300 0.000 0.01213.400 0.508 0.528L 12.900L1 2.850 3.250 0.112 0.128 V 7.500 REF. 0.295 REF.Φ 3.400 3.800 0.134 0.150Attention:■Any and all NCE power products described or contained herein do not have specifications that can handle applications that require extremely high levels of reliability, such as life-support systems, aircraft's control systems, or other applications whose failure can be reasonably expected to result in serious physical and/or material damage. Consult with your NCE power representative nearest you before using any NCE power products described or contained herein in such applications.■ NCE power assumes no responsibility for equipment failures that result from using products at values that exceed, even momentarily, rated values (such as maximum ratings, operating condition ranges, or other parameters) listed in products specifications of any and all NCE power products described or contained herein.■Specifications of any and all NCE power products described or contained herein stipulate the performance, characteristics, and functions of the described products in the independent state, and are not guarantees of the performance, characteristics, and functions of the described products as mounted in the customer’s products or equipment. To verify symptoms and states that cannot be evaluated in an independent device, the customer should always evaluate and test devices mounted in the customer’s products or equipment.■ NCE power Semiconductor CO.,LTD. strives to supply high-quality high-reliability products. However, any and all semiconductor products fail with some probability. It is possible that these probabilistic failures could give rise to accidents or events that could endanger human lives, that could give rise to smoke or fire, or that could cause damage to other property. When designing equipment, adopt safety measures so that these kinds of accidents or events cannot occur. Such measures include but are not limited to protective circuits and error prevention circuits for safe design, redundant design, and structural design.■ In the event that any or all NCE power products(including technical data, services) described or contained herein are controlled under any of applicable local export control laws and regulations, such products must not be exported without obtaining the export license from the authorities concerned in accordance with the above law.■No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, or any information storage or retrieval system, or otherwise, without the prior written permission of NCE power Semiconductor CO.,LTD.■Information (including circuit diagrams and circuit parameters) herein is for example only ; it is not guaranteed for volume production. NCE power believes information herein is accurate and reliable, but no guarantees are made or implied regarding its use or any infringements of intellectual property rights or other rights of third parties.■ Any and all information described or contained herein are subject to change without notice due to product/technology improvement, etc. When designing equipment, refer to the "Delivery Specification" for the NCE power product that you intend to use.■This catalog provides information as of Sep.2010. Specifications and information herein are subject to change without notice.。

金丰2号棉种审定公告一、引言金丰2号棉种是一种新型的棉花种植品种，经过审定后正式发布。

本文将详细介绍金丰2号棉种的审定公告内容，包括审定的背景、审定的过程和结果等。

二、审定背景为了提高我国棉花的品质和产量，推动棉花产业的发展，农业部决定对新品种金丰2号棉种进行审定。

金丰2号棉种是由农业科学研究院研发的一种新型棉花品种，具有抗病虫害、高产、优质等特点，有望在我国棉花种植业中发挥重要作用。

三、审定过程3.1 申请材料的准备农业科学研究院在申请金丰2号棉种审定之前，先进行了大量的实验和研究工作。

他们收集了金丰2号棉种的相关数据和试验结果，并编制了详细的申请材料，包括品种特征、栽培技术、产量和品质等方面的数据。

3.2 专家组的评审农业部组织了由专家组成的评审团队，对金丰2号棉种的申请材料进行评审。

评审专家对申请材料进行了仔细研究，并进行了多次讨论和交流。

他们结合自己的专业知识和实践经验，对金丰2号棉种的品质、产量、抗病虫害等方面进行了全面评估。

3.3 田间试验为了验证金丰2号棉种的表现和性状，农业科学研究院进行了大规模的田间试验。

他们在不同的地区和环境条件下，种植了金丰2号棉种，并对其进行了观察和记录。

通过田间试验，他们进一步验证了金丰2号棉种的抗病虫害能力、适应性和产量等方面的特点。

3.4 结果公示和听证会在评审过程结束后，农业部公示了金丰2号棉种审定的初步结果，并组织了听证会。

听证会上，各方对金丰2号棉种的审定结果提出了自己的意见和建议。

农业部在听取各方意见的基础上，对审定结果进行了进一步的调整和完善。

3.5 最终审定结果经过上述的各项工作，农业部最终确定了金丰2号棉种的审定结果。

根据评审专家的意见和田间试验的结果，金丰2号棉种被认定为一种具有优良品质和高产能力的棉花品种。

农业部决定正式发布金丰2号棉种的审定公告，并推广其种植和应用。

四、审定结果根据农业部的审定公告，金丰2号棉种具有以下特点和优势： 1. 抗病虫害能力强：金丰2号棉种对多种棉花常见病虫害具有较高的抵抗力，能够减少农药的使用。

糠醛二线基础油参数引言糠醛二线基础油是一种重要的化工原料，广泛应用于润滑油、涂料、胶粘剂等领域。

本文将详细介绍糠醛二线基础油的参数，包括物理性质、化学性质、生产工艺等方面，以便更好地了解和应用这一产品。

物理性质糠醛二线基础油的物理性质是衡量其品质和适用性的重要指标之一。

以下是常见的物理性质参数：密度密度是指单位体积内所含物质的质量。

糠醛二线基础油的密度通常在0.85-0.95g/cm³之间，可以根据具体需求进行调整。

粘度粘度是指流体抵抗流动的程度。

糠醛二线基础油的粘度范围较广，通常在10-1000 mm²/s之间，可根据不同应用领域进行选择。

闪点闪点是指在特定条件下液体蒸发产生可燃气体与空气混合后能被引燃的最低温度。

糠醛二线基础油的闪点通常在100-200℃之间，具有较高的安全性。

凝固点凝固点是指液体在降温过程中开始结晶凝固的温度。

糠醛二线基础油的凝固点通常在-10℃以下，适用于低温环境下的使用。

可溶性可溶性是指糠醛二线基础油与其他物质之间的相容性和溶解性。

糠醛二线基础油具有良好的可溶性，可以与多种添加剂和其他润滑剂进行混合使用。

化学性质除了物理性质外，糠醛二线基础油的化学性质也是评价其品质和适用性的重要因素。

以下是常见的化学性质参数：酸值酸值是指单位质量内含有的总酸量。

糠醛二线基础油通常具有较低的酸值，一般在0.01 mgKOH/g以下。

碱值碱值是指单位质量内所需要加入碱液以中和其中所有强酸的量。

糠醛二线基础油的碱值通常较低，一般在0.01 mgKOH/g以下。

水分水分是指糠醛二线基础油中所含的水的含量。

糠醛二线基础油通常要求水分含量低于0.05%。

硫含量硫含量是指糠醛二线基础油中所含的硫元素的百分比。

糠醛二线基础油通常要求硫含量低于0.5%。

生产工艺糠醛二线基础油的生产工艺对其品质和性能有着重要影响。

以下是生产工艺中常用的步骤：原料准备选择优质稻谷作为原料，经过清洗、脱壳等处理，得到高纯度的稻壳。

40%乙二醛溶液熔点英文回答：Melting Point of 40% Glyoxal Solution.Glyoxal, also known as ethanedial, is an organic compound with the formula CHOCHO. It is a colorless liquid with a pungent odor. Glyoxal is used in the production of textiles, dyes, and pharmaceuticals.A 40% glyoxal solution is a mixture of 40% glyoxal and 60% water. The melting point of a 40% glyoxal solution is -12°C (10.4°F). This is lower than the melting point of pure glyoxal, which is -15°C (5°F).The melting point of a solution is the temperature at which the solid and liquid phases of the solution are in equilibrium. At the melting point, the solid and liquid phases have the same vapor pressure. The melting point of a solution is affected by the concentration of the solution.The more concentrated the solution, the lower the melting point.The melting point of a 40% glyoxal solution can be used to determine the concentration of the solution. If the melting point of a solution is lower than the melting point of pure glyoxal, then the solution is more concentratedthan 40%. If the melting point of a solution is higher than the melting point of pure glyoxal, then the solution isless concentrated than 40%.中文回答：40%乙二醛溶液的熔点。

河南农业2017年第4期（上）田间覆盖率为75％左右，一年生阔叶杂草主要以播娘蒿、荠荠菜为优势种群，杂草平均株高5~8 cm，生育期主要为3~5叶期。

三、试验设计和安排（一）药剂1.试验药剂双氟磺草胺·二甲四氯异辛酯（40%悬浮剂）（河南金田地农化有限责任公司提供）。

2.对照药剂双氟磺草胺（50 g/L 悬浮剂）（美国陶氏益农公司生产，市售品）。

二甲四氯钠（56%可溶性粉剂）（山东盛邦绿野化学有限公司生产，中午进行；人工除草于喷药结束后随即进行，用铁锄浅锄1遍，力求均匀一致。

4.施用容量喷液量为750 L/hm 2。

5.防治病虫和非靶标杂草药剂资料于2015年3月21日施用12.5% 烯唑醇可湿性粉剂防治小麦纹枯病1次，4月16日施用10%吡虫啉可湿性粉剂防治小麦蚜虫1次， 5月4日施用2.5%高效氯氰菊酯乳油和50%多菌灵可湿性粉剂防治小麦蚜虫、赤霉病1次，未使用除草剂防治其他杂草。

于2014年12月15日和2015年3月15日各浇水1次，于2015年3月21日施用12.5%烯唑醇可湿性粉剂防治小麦纹枯病1次，4月16日施用10%吡虫啉可湿性粉剂防治小麦蚜虫1次， 5月4日施用2.5%高效氯氰菊酯乳油和50%多菌灵可湿性粉剂防治小麦蚜虫、赤霉病1次。

(二)调查方法、时间和次数共调查3次，分别为2015年3月7日（施药当天），3月27日（施药后20 d），4月16日（施药后40 d）。

(三)杂草调查调查采用5点取样法，每小区双氟磺草胺·二甲四氯异辛酯（40%NONG YAO YU ZHI BAO农药与植保河南农业2017年第4期（上）NONG YAO YU ZHI BAO农药与植保空白对照区每667 m 2产量五、结果与分析由试验结果可知：通过施药后观察，试验各小区处理对小麦生长均安全、无药害。

供试药剂双氟磺草胺·二甲四氯异辛酯（40%悬浮剂）对冬小麦田一年生阔叶杂草具有较好防除效果，其有效成分300 g/hm 2、360 g/hm 2、420 g/hm 2、720 g/hm 24个处理，药后20 d 株防效分别达78.70%、85.23%、88.56%、91.47%；药后40 d 株防效分别达83.67%、89.11%、92.22%、94.70%，药后40 d 鲜质量防效分别个处理间无显著性差异，供试药剂双氟磺草胺·二甲四氯异辛酯（40%悬浮剂）有效成分360 g/hm 2与人工除草间无显著性差异，供试药剂双氟磺草胺·二甲四氯异辛酯（40%悬浮剂）有效成分300 g/hm 2与人工除草间无显著性差异，上述各小区处理均与对照药剂二甲四氯钠（56%可溶性粉剂）有效成分672 g/hm 2存在差异显著性。

GP02-20 THRU GP02-40HIGH VOLTAGE GLASS PASSIVATED JUNCTION RECTIFIERReverse Voltage -2000 to 4000 Volts Forward Current -0.25 AmpereFEATURES♦ Plastic package has Underwriters LaboratoryFlammability Classification 94V-0♦ High temperature metallurgically bonded construction♦ Glass passivated cavity-free junctions♦ Capable of meeting environmental standards of MIL-S-19500♦ High temperature soldering guaranteed:350°C/10 seconds, 0.375" (9.5mm) lead length,5 lbs.(2.3kg) tensionMECHANICAL DATARatings at 25°C ambient temperature unless otherwise specified.GP02GP02GP02GP02GP02SYMBOLS-20-25-30-35-40UNITSMaximum repetitive peak reverse voltage V RRM 20002500300035004000Volts Maximum RMS Voltage V RMS 14001750210024502800Volts Maximum DC blocking voltageV DC 20002500300035004000Volts Maximum average forward rectified current 0.375" (9.5mm) lead length at T A =55°CI (AV)0.25Amp Peak forward surge current8.3ms single half sine-wave superimposed on rated load at:I FSM 15.0Amps (JEDEC Method)T A =55°C Maximum instantaneous forward voltage at 1.0A V F 3.0Volts Maximum DC reverse current T A = 25°C 5.0at rated DC blocking voltageT A =100°CI R 50.0µA Typical reverse recovery time (NOTE 1)t rr 2.0µs Typical junction capacitance (NOTE 2)C J 3.0pF Typical thermal resistance (NOTE 3)R ΘJA 130.0°C/W Operating junction and storage temperature rangeT J , T STG-65 to +175°CNOTES:(1) Reverse recovery test conditions:I F =0.5A, I R =1.0A, I rr =0.25A (2) Measured at 1.0 MHz and applied reverse voltage of 4.0 Volts(3) Thermal resistance from junction to ambient at 0.375" (9.5mm) lead lengths, P .C.B.mounted4/98P A1.03.04.05.06.07.08.00751501750.050.10.150.20.25 2.00.0110.111010002.03.04.05.06.01010015105.01100.11.0025501001250.011100.120406080100RATINGS AND CHARACTERISTIC CURVES GP02-20 THRU GP02-40FIG.1 - FORWARD CURRENT DERATINGAMBIENT TEMPERATURE, °CA V E R A G E F O R W A R D R E C T I F I E D C U R R E N T , A M P E R E SFIG.2 - MAXIMUM NON-REPETITIVE PEAKFORWARD SURGE CURRENTNUMBER OF CYCLES AT 60 H ZP E A K F O R W A R D S U R G E C U R R E N T , A M P E R E SFIG.3 - TYPICAL INSTANTANEOUS FORWARDCHARACTERISTICSFIG.4 - TYPICAL REVERSE CHARACTERISTICSI N S T A N T A N E O U S F O R W A R D C U R R E N T ,A M P E R E SI N S T A N T A N E O U S R E V E R S E L E A K A G E C U R R E N T , M I C R O A M P E R E SINST ANT ANEOUS FORWARD VOLT AGE,VOLTSPERCENT OF RATED PEAK REVERSEVOLT AGE, %FIG.5 - TYPICAL JUNCTION CAPACITANCEJ U N C T I O N C A P A C I T A N C E , p FREVERSE VOLT AGE, VOLTST J =100°CT J =25°CT J =25°CPULSE WIDTH=300µs 1%DUTY CYCLET J =25°C f=1.0 MH ZVsig=50mVp-p0.375" (9.5mm)LEAD LENGTH60 H Z RESISTIVE OR INDUCTIVE LOADT J =T J max.8.3ms SINGLE HALF SINE-WAVE (JEDEC Method)。

BC防老剂4020的性能和用途D4020又称防老剂DMBPPO，密度0.986-1.00。

熔点7.3.6℃。

温度超过35-40℃时会慢慢结块。

溶于苯、丙酮、乙酸乙酯、二氯乙烷、甲苯，不溶于水。

暴露于空气中颜色变深。

防老剂4020雨后淋水检验记录是轮胎特别是子午胎生产用重要添加剂。

产品供求分析A生产现状目前世界上主要对苯二胺类橡胶防老剂生产企业有美荷联营的富兰克斯公司、美国开普顿公司、捷克的爱格富集团、德国朗盛公司等，这四家公司拥有全球约80%B2005年我国对苯二胺类橡胶防老剂生产能力约为42kt/aC4020的生产能力为24kt/a，主要生产企业采取重复建设新生产线的方法来扩大生产能力。

D橡胶防老剂4020目前国内共有七家企业生产，其中主要的两家分别是南化公司化工厂和山东圣奥化工有限公司，生产能力约占全国生产能力的75%8.1.4国外一些跨国公司早已开始调整生产布局，减少生产布点，通过提高单套装置能力来提高总体生产规模，实现规模效益。

德国朗盛公司与铜峰股份有限公司和铜陵信达化工公司合作生产对苯二胺类橡胶防老剂及其中间体项目于2006年开始启动，计划建设20kt/a 防老剂4020及配套中间体对氨基二苯胺项目；德国艾尔派克公司独资成立的镇江爱扬化工有限公司，总投资1600万美元生产高端橡胶助剂项目；英国斯夫特实业有限公司决定投资2700万美元在山东宁阳县建设年产4A万吨橡胶防老剂项目，项目签约仪式已于2005年B月1日举行。

另外国际C橡胶助剂巨头富莱克斯公司和康普顿公司一直与国内相关企业和部门洽谈，寻求合作生产橡胶助剂，主要意向集中在对苯二胺类和喹啉类防老剂方面。

D需求预测我国橡胶防老剂大致分为对苯二胺类、RD、二苯胺类、酚类、其他等5细部构造2-1。

设计要求，施工措施，观察记录2-1我国橡胶防老剂消费比例AB防老剂品种C比例（%D11、对苯二胺类B 表示可能违反强制性条文，经检测单位检测，设计单位核定后，再判定；C 表示违反强制性条文；D 表示严重违反强制性条文。