An experimental and numerical investigation into the effects of the PZT actuator shape in polymethylmethacrylate (PMMA) peristaltic micropumps

Hsu, Yi-Chu; Hsu, Jui‐Ming; Le, Ngoc-Bich

doi:10.1007/s00542-008-0761-6

Cited by 6 publications

(2 citation statements)

References 10 publications

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“…Based on the fluid incompressibility, it can be taken for that the velocity of fluid in the chamber and the piston are the same [14,15]. Supposing the fluid velocity in chamber changed a little ∆v in a ultrashort time interval ∆t, the pressure changes,…”

Section: ) Mechanical and Aerospace Engineering Icmae2011mentioning

confidence: 99%

Inertial Flow Phenomenon Analysis on Piezoelectric Pump

Liu

Yang

2011

AMM

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The author finds that there is outflow during piezoelectric pump sucking process, and a dynamic model combined with hydrodynamics and mechanical vibration is presented for the anlysis of piezoelectric pump sucking process phenomenon. The model is utilized to study the reason of sucking process outflow and the effect of the driving frequency, outlet valve rigidity, the load in inlet and outlet on the sucking process outflow. The result turns out that the flow inertia is the cause of sucking process outflow; the inertial flow also exists during draining process as the sucking process; increasing driving frequency, or outlet valve rigidity, the inertial flow decreases, increasing the load in inlet and outlet has the same effect. The research makes it clear that the pump output flow should include two parts, bulk flow and inertial flow, which will provide theory reference for the precise flow control of piezoelectric pump.

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Section: ) Mechanical and Aerospace Engineering Icmae2011mentioning

confidence: 99%

Inertial Flow Phenomenon Analysis on Piezoelectric Pump

Liu

Yang

2011

AMM

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“…In addition to experimental investigation of micropumps' performance, mathematical modeling has been used to predict the performance and interpret the experimental data of micropumps [3,[10][11][12][13][14][15][16][17]. For example, Chandika et al [3] developed a mathematical model of a piezoelectric-driven diffuser-nozzle type micropump.…”

Section: Introductionmentioning

confidence: 98%

Understanding frequency response of thermal micropumps using electrical network analogy

Bardaweel

2014

Can. J. Phys.

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In this article the frequency response of a thermal micropump is investigated using electrical network analogy modeling technique. This technique is based on dividing the micropump into subsystems and representing each subsystem using the equivalent network analogy. Obtained mathematical models of subsystems are then represented using transfer functions and block diagrams. As an example, thermopneumatic micropump is considered. Model simulation suggests an increase in the net flow rates of the micropump as the operating frequencies increased, until a first cut-off frequency is reached. A second cut-off frequency is observed with further increase in operating frequencies. Model simulations are consistent with qualitative experimental trends reported in the literature. The model is used to obtain a relationship between cut-off frequencies and design properties of the micropump. Model simulations show that lower cut-off frequency is related to mechanical properties of the thermopneumatic micropump, including stiffness and damping. Upper cut-off frequency is related to thermal properties of the thermopneumatic micropump, including thermal conductivity, heat capacity, and working fluid density.Résumé : Nous étudions ici la réponse en fréquence d'une micro-pompe thermique en utilisant une technique de modélisation par réseau électrique analogue. Selon cette technique, nous divisons la micro-pompe en sous-systèmes et chaque sous-système est représenté par un réseau analogue. La modélisation mathématique fait alors appel à des fonctions de transfert et à des schémas fonctionnels. Pour fin d'exemple, nous étudions une micro-pompe thermo-pneumatique. La modélisation suggère une augmentation du débit avec la fréquence jusqu'à une première fréquence de coupure. Une augmentation subséquente de la fréquence nous amène à une seconde fréquence de coupure. Ces simulations sont cohérentes avec les tendances qualitatives expérimentales rapportées dans la littérature. Nous utilisons le modèle pour obtenir la relation entre les fréquences de coupure et le design de la micro-pompe. Les simulations montrent que la fréquence de coupure la plus basse est reliée aux propriétés mécaniques de la micro-pompe thermo-pneumatique, incluant la rigidité et l'amortissement. La fréquence supérieure est reliée aux propriétés thermiques de la micro-pompe, incluant la conductivité thermique, la capacité calorifique et la densité du fluide pompé. [Traduit par la Rédaction]

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