1) squeezed vacuum state
压缩真空态
1.
Squeezing effects of the photon-added squeezed vacuum states;
增光子压缩真空态的压缩特性
2.
The higher-order squeezing properties for the states generated by excitations on a squeezed vacuum state are studied.
发现θ等于零时这种态中正交分量的2N 阶矩表达式可以化为压缩真空态的2N 阶矩和一个与 m有关的函数相乘的形式。
3.
Based upon the quantization of a mesoscopic lossless transmission line, analysis is made for the quantum fluctuations of the current and current gradient of the line in the vacuum state and squeezed vacuum state, especialy for the difference between the quantum fluctuations of the transmission line and LC circuit.
在将介观无损耗传输线量子化的基础上 ,研究了真空态和压缩真空态下传输线中电流和电流梯度的量子涨落 。
2) squeezing vacuum state
压缩真空态
1.
The study shows: considering the coupling effects of the mesoscopic capacitor, the mesoscopic LC circuit will evolve from the vacuum state to a squeezing vacuum state.
研究表明:介观LC电路将由初始的真空态演化到压缩真空态,并对压缩真空态下的量子涨落进行研究。
3) squeezed vacuum
压缩真空态
1.
Teleportation of quantum states by means of two-mode squeezed vacuum;
利用双模压缩真空态实现量子态的远程传输
2.
Starting from the equation for parallel connection circuit of RLC with source,the quantum fluctuations of the current and voltage in excitation state of squeezed vacuum state are evaluated by quantizing RLC circuit with source,and the results are discussed.
从有源并联 RLC电路运动方程出发 ,通过量子化的有源 RLC电路计算了在压缩真空态的激发态下电荷和电流的量子涨落 ,并对结果进行了讨论 。
3.
In this paper,we have investigated the phase statistical properties of squeezed vacuum field interacting with an atom using the Pegg-Barnett phase theory.
本文应用Pegg-Barnet位相理论,研究了与原子相互作用的压缩真空态场的位相统计特性;与单一压缩真空态场位相特性比较,讨论了原子与压缩真空态场相互作用对场的位相特性的影响。
4) two-mode squeezed vacuum state
双模压缩真空态
1.
Quantum entanglement in system of two-mode squeezed vacuum state interacting with Bose-Einstein condensate;
双模压缩真空态与玻色-爱因斯坦凝聚相互作用系统中的量子纠缠
2.
It calculates the result of the quadrature-amplitude measurement on the first-mode field of a two-mode squeezed vacuum state via the entangled state representation,and it is shown that the second-mode field collapses to a single-mode squeezed state,whose explicit form is derived.
对文献[4]的结果作了进一步推导,用纠缠态表象方法计算了对双模压缩真空态第一个模场作正交振幅分量测量的结果,发现第二个模塌缩到一个压缩态,其显式被导出。
3.
The K-th power H-squeezing properties of photon field for the two-mode squeezed vacuum state|ξ>=1coshr∑∞n=0(-e~(iθ)tanhr)~n|n,n> are numerically studied.
用数值计算的方法研究了双模压缩真空态|ξ〉=1coshr∑∞n=0(-eiθtanhr)n|n,n〉的K次方H压缩特性。
5) Excited squeezed vacuum state
激发压缩真空态
1.
A quantization scheme for an LC circuit a source was proposed and the fluctuations of the charge and the magnetic flux of the circuit in excited squeezed vacuum state are studied by using the complete quantum theory.
通过量子化LC电路,运用全量子理论研究了在激发压缩真空态下介观LC电路中电荷、磁通量的量子涨落。
6) two-mode squeezing vacuum state
双模压缩真空态
1.
Entanglement and decoherence in the interaction between two-mode squeezing vacuum state field and atom;
双模压缩真空态与原子相互作用中的量子纠缠和退相干
2.
By considering the in- teraction between the two-mode squeezing vacuum state field and the environment(atoms),we investigate the quantum information fidelities of the atoms the field and the system in two- mode squeezing vacuum state Tavis-Cummings model.
考虑了原子的偶极相互作用,通过计算Tavis-Cummings模型下压缩真空态的保真度,阐明了在双模压缩真空态与环境(原子)通过双光子发生相互作用过程中量子信息的保真程度随时间的演化关。
3.
By considering the interaction between the two-mode squeezing vacuum state field and the environment(atoms),we investigate the the cross-correlation function between atoms in two-mode squeezing vacuum state Tavis-Cummings model.
通过计算Tavis-Cummings模型下压缩真空态的原子关联,阐明了在双模压缩真空态与环境(原子)通过双光子发生相互作用过程中量子关联随时间的演化关系。
补充资料:2BV系列水环式真空泵及压缩机
概述
2BV系列水环真空泵适用于抽除气体和水蒸气,吸气压力可以达到33mbar绝压(97%真空度)。当用变压器油作为工作液时(称为油环真空泵),吸气压力可达到6.7mbar绝压(99.3%真空度),可以完全取代往复式真空泵。当真空泵在吸气压力接近极限真空下长期工作时,应联接气蚀保护管,以对泵进行保护。作为压缩机用时,其压力最大至0.26MPa(绝压)。2BV系列水环真空泵作为新一代节能型产品,其以出色的性能及众多优点将全面取代同性能的SK、2SK、W、WY、WL系列水环真空泵、往复真空泵。
相对于国内同类型SK、2SK、SZ等水环式真空泵,其有以下特点:
机泵同轴式直联设计,节省空间,易于安装。
全部采用国外进口机械密封作为标准配置。
运行平稳,噪音可低至62分贝。
铝青铜叶轮强度高,经久耐用,并提高了泵的耐腐蚀性。
独特的柔性排气口设计,不会产生过压缩,确保了2BV在其性能范围内效率最佳。
全部采用Y2系列电机,防护等级IP54(普通为IP44)
真空过滤 | (化学制品过滤厂,化学制品处理厂,铁矿厂,采矿业,磷肥厂,造纸厂,家禽加工厂,选煤厂) | 蒸汽回收 | (蒸馏器,装卸站) |
水泵引水 | (自来水厂) | ||
冷凝器水箱补水 | (电站) | ||
真空蒸馏 | (牛奶厂,食品厂,化工厂,纸浆厂) | 烘干 | (化工、医药制造业) |
真空消毒 | (医院,医务室,实验室) | 木材处理/干燥 | |
挤出成型 | (塑料行业) | 医药/实验室真空 | |
成型 | (塑料,聚乙烯,橡胶,轮胎等制造业) | 溶剂回收 | |
浸渍 | (食品加工,木器加工,纺织厂,胶合板厂,电线杆的制造等) | 土壤净化 | |
真空包装 | |||
液体脱气 | (食品加工,水软化,瓶装厂) | 萃取 | |
压缩空气再生 | (纸浆,钢铁,汽车,玻璃,化工) | 制革 | |
食品加工 | (食品加工厂,牛奶厂) | 罐装 |
技术参数
曲线 编号 | 产品型号 | 最大气量 m3/min | 极限真空度 mbar(MPa) | 电机功率(轴功率) kW | 泵转速 r.p.m | 工作液流量 L/min | 噪音 dB(A) | 重量 kg |
60V | 2BV2 060 | 0.45 | 33mbar (-0.097MPa) | 1.1(0.81) | 2880 | 2 | 62 | 37 |
61V | 2BV2 061 | 0.86 | 1.5(1.45) | 2880 | 2 | 65 | 41 | |
70V | 2BV2 070 | 1.33 | 3(2.35) | 2850 | 2.5 | 66 | 66 | |
71V | 2BV2 071 | 1.83 | 4(3.85) | 2860 | 4.2 | 72 | 85 | |
110V | 2BV5 110 | 2.75 | 4 | 1450 | 6.7 | 63 | 120 | |
111V | 2BV5 111 | 3.83 | 5.5 | 1450 | 8.3 | 68 | 150 | |
121V | 2BV5 121 | 4.66 | 7.5 | 1450 | 10 | 69 | 210 | |
131V | 2BV5 131 | 6.66 | 11 | 1430 | 15 | 73 | 280 | |
161V | 2BV5 161 | 8.33 | 15 | 970 | 20 | 74 | 390 | |
110V | 2BV6 110 | 2.75 | 4 | 1450 | 6.7 | 63 | 148 | |
111V | 2BV6 111 | 3.83 | 5.5 | 1450 | 8.3 | 68 | 196 | |
121V | 2BV6 121 | 4.66 | 7.5 | 1450 | 10 | 69 | 220 | |
131V | 2BV6 131 | 6.66 | 11 | 1430 | 15 | 73 | 314 | |
161V | 2BV6 161 | 8.33 | 15 | 970 | 20 | 74 | 426 |
选型示例:
①设计点参数:
吸气量v=100m3/h
吸气压力P1=40mbar
②其余参数同标准状态(见注)
选择与设计点①最接近的一条曲线
③本例中为71V
根据曲线编号查出相应的产品型号
(即定贷号,但仅限于标准型)
如本例中可从71V中查得泵型为
2BV2071-ONC06-1p
注:该性能曲线是在吸入介质为20℃的饱和空气,工作液温度15℃,排气压力1013mba的状态下得到的。性能允许差±10%,图中左侧为配用大气喷射器的性能曲线。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条