TY - JOUR
T1 - Modelling and experimental characterisation of a magnetic shuttle pump for microfluidic applications
AU - Nico, Valeria
AU - Dalton, Eric
N1 - Publisher Copyright:
© 2021 The Author(s)
PY - 2021/11/1
Y1 - 2021/11/1
N2 - Microfluidic technology witnessed a fast growth in recent years thanks to its diverse nature that allows its use in a wide range of industries including microelectronics, aerospace, telecommunications, biomedical and pharmaceutical. One of the limiting issues for the implementation of microfluidics in high end electronics or biomedical devices is that pumps are not able to develop the required flow rates and pressures. A novel magnetic shuttle pump (MSP) technology that can achieve class-leading pressure and flow rate and a numerical model are presented in this paper. The MSP technology consists of an oscillating neodymium ring shuttle magnet housed in a solenoid driver. Two counter-wound copper coils are used to oscillate the shuttle magnet. The numerical model couples the electromagnetic and fluidic properties of the MSP by taking into account the forces acting on the shuttle magnet. The model is used to predict the pump characteristics of two MSPs with different size: the MSP1.7 with overall volume 1.7 cm3 and MSP3.3 with overall volume 3.3 cm3. Simulations and experimental characterisation were carried out considering an electric driving power of 1W. Experimentally, a maximum pressure Pmax = 43.53 kPa and a maximum flow rate Q˙ = 46.69 ml/min were achieved by the MSP1.7, while a maximum pressure Pmax = 21.74 kPa and a maximum flow rate Q˙ = 205.99 ml/min were achieved by the MSP3.3. Due to the close agreement between the experimental and simulated data, the model can be used in the future to modify the design of the MSP to achieve the required Pressure/Flow characteristics.
AB - Microfluidic technology witnessed a fast growth in recent years thanks to its diverse nature that allows its use in a wide range of industries including microelectronics, aerospace, telecommunications, biomedical and pharmaceutical. One of the limiting issues for the implementation of microfluidics in high end electronics or biomedical devices is that pumps are not able to develop the required flow rates and pressures. A novel magnetic shuttle pump (MSP) technology that can achieve class-leading pressure and flow rate and a numerical model are presented in this paper. The MSP technology consists of an oscillating neodymium ring shuttle magnet housed in a solenoid driver. Two counter-wound copper coils are used to oscillate the shuttle magnet. The numerical model couples the electromagnetic and fluidic properties of the MSP by taking into account the forces acting on the shuttle magnet. The model is used to predict the pump characteristics of two MSPs with different size: the MSP1.7 with overall volume 1.7 cm3 and MSP3.3 with overall volume 3.3 cm3. Simulations and experimental characterisation were carried out considering an electric driving power of 1W. Experimentally, a maximum pressure Pmax = 43.53 kPa and a maximum flow rate Q˙ = 46.69 ml/min were achieved by the MSP1.7, while a maximum pressure Pmax = 21.74 kPa and a maximum flow rate Q˙ = 205.99 ml/min were achieved by the MSP3.3. Due to the close agreement between the experimental and simulated data, the model can be used in the future to modify the design of the MSP to achieve the required Pressure/Flow characteristics.
KW - Electromagnetic
KW - Microfluidics
KW - Micropump
UR - http://www.scopus.com/inward/record.url?scp=85108999270&partnerID=8YFLogxK
U2 - 10.1016/j.sna.2021.112910
DO - 10.1016/j.sna.2021.112910
M3 - Article
AN - SCOPUS:85108999270
SN - 0924-4247
VL - 331
JO - Sensors and Actuators, A: Physical
JF - Sensors and Actuators, A: Physical
M1 - 112910
ER -