1.How to provide the energy for the blood pump is one of the key problem in researching of artificial heart.
血泵供能方式是人工心脏研究的关键之一。
2.Simulations of the acceleration process were done using ADAMS, and the speed curves and acceleration curves of the blood pump were obtained.
利用ADAMS进行血泵加速过程的动力学仿真,得到粗略的血泵加速曲线及加速度曲线。
3.Finally, we established the mathematical formula of blood pump in different conditions (normal and suction) to evaluate the hemolytic value.
最终建立了能够定量评价血泵在不同工作状态下(正常状态和抽吸状态)溶血程度的数学公式。
4.The blood pump works based on non-contact magnetic coupling drive; and comprises a pump body and a drive mechanism in vitro.
该血泵采用无接触式磁耦合传动方式,由设置在体内的泵体和设置在体外的驱动装置两部分组成。
5.relative angle and magnetic pole number between driving magnetic gear and driven magnetic gear of blood pump driving system.
计算血泵驱动系统的主动轮和从动轮之间的距离、相对转角以及磁极对数对血泵传动扭矩的影响。
6.Thus the theoretical basis for the design of conical spiral magnetic suspension blood pump was provided.
为锥形螺旋磁悬浮血泵的设计提供了理论依据。
7.The blood pump and the artificial heart is constituted by air exhausting and compressing machine, connecting pipe and pump.
组合式气动心肺机由血泵,回流罐,变温器及动脉微栓过滤器组合而成。
8.The invention provides an implantable non-contact miniature axial flow blood pump for circulation support in patients with heart failure.
一种植入式无接触微型轴流血泵,可用于辅助衰竭心脏的血液循环。
9.During the design procedure for axial flow blood pump, proper blade number is important to whole flow performance in the pump.
在人工轴流心脏泵的设计过程中,叶片数目的选取对泵的工作条件的影响很大。
10.The blood pump output was coincided with control object model and control system response met the equiments of control system.
血泵电机的输出与控制目标模型相符,控制系统的响应满足控制性能的要求。