Design, fabrication and experimental studies of compliant flexure diaphragm for micro pump
-
2018-04-20 
https://doi.org/10.14419/ijet.v7i2.21.11838
-
Compliant, out-of-plane, PVDF (Polyvinylidene fluoride), flexure, micro pump -
This study reports the performance of piezo actuated compliant flexure diaphragm for micropump and MEMS application. To achieve the high performance of diaphragm at the low operating voltage compliant flexure diaphragm design is introduced. Very limited work has done on the diaphragms of micropump. Large numbers of mechanical micropumps have used plane diaphragms. The central deflection of diaphragm plays an important role in defining the micropump performance. The flow rate of mechanical type micropump strongly depends on the central deflection of diaphragm. In this paper compliant flexure diaphragms are designed for micropump to achieve higher deflection at lower operating voltage. Finite element analysis of compliant flexure diaphragm with single layer PVDF (Polyvinylidene fluoride) actuator is simulated in COMSOL. Compliant flexure diaphragms with a different number of flexures are analyzed. The central deflection of compliant flexure diaphragms is measured for driving voltages of 90V to 140V in 10 steps. The deflection of the compliant flexure diaphragm mainly depends on flexure width and length, the number of flexures in the diaphragm, PVDF thickness, diaphragm thickness and driving voltage. Use of compliant flexure diaphragm for micropump will reduce the mass and driving voltage of micropump. An attempt is made to compare the results of compliant flexure diaphragms with plane diaphragms. From the experimental results it is noticed that the compliant flexure diaphragm deflection is twice that of the plane diaphragm at same driving voltage. Deflection of three flexure and four flexure compliant diaphragms is 10.5µm and 11.5µm respectively at 140V.
Â
Â
-
References
[1] Awtar S & Slocum AH, Flexure systems based on a symmetric diaphragm flexure. ASPE1803, (2005).
[2] Azarbadegan A, Cortes-Quiroz CA, Eames I & Zangeneh M, “Analysis of double-chamber parallel valveless micropumpsâ€, Microfluidics and Nanofluidics, Vol.9, No.2-3, (2010), pp.171-180.
[3] Bourouina T, Bossebuf A & Grandchamp JP, “Design and simulation of an electrostatic micropump for drug-delivery applicationsâ€, Journal of Micromechanics and Micro engineering, Vol.7, No.3, (1997).
[4] Böhm S, Olthuis W & Bergveld, P, “A plastic micropump constructed with conventional techniques and materialsâ€, Sensors and Actuators A: Physical, Vol.77, No.3, (1999), 223-228.
[5] Carrozza MC, Croce N, Magnani B & Dario P, “A piezoelectric-driven stereo lithography-fabricated micro pumpâ€, Journal of Micromechanics and Micro engineering, Vol.5, No.2, (1995).
[6] Deshpande M & Saggere L, “An analytical model and working equations for static deflections of a circular multi-layered diaphragm-type piezoelectric actuatorâ€, Sensors and Actuators A: Physical, Vol.136, No.2, (2007), pp.673-689.
[7] Huang CW, Huang SB & Lee GB, “Pneumatic micro pumps with serially connected actuation chambersâ€, Journal of micromechanics and micro engineering, Vol.16, No.11, (2006).
[8] Kan J, Tang K, Liu G, Zhu G & Shao C, “Development of serial-connection piezoelectric pumpsâ€, Sensors and Actuators A: Physical, Vol.144, No.2, (2008), pp.321-327.
[9] Kota S, Joo J, Li Z, Rodgers SM & Sniegowski J, “Design of compliant mechanisms: applications to MEMSâ€, Analog integrated circuits and signal processing, Vol.29, No.1-2, (2001), pp.7-15.
[10] Jeong OC & Yang SS, “Fabrication and test of a thermo pneumatic micropump with a corrugated p+ diaphragmâ€, Sensors and Actuators A: Physical, Vol.83, No.1, (2000), pp.249-255.
[11] Howell, L. L., Magleby, S. P., & Olsen, B. M. (Eds.). (2013). Handbook of compliant mechanisms. John Wiley & Sons.
[12] Kota S, Joo J, Li Z, Rodgers SM & Sniegowski J, “Design of compliant mechanisms: applications to MEMSâ€, Analog integrated circuits and signal processing, Vol.29, No.1-2, (2001), pp.7-15.
[13] Lobontiu N, “Out-of-Plane (Diaphragm) Compliances of Circular-Axis Notch Flexible Hinges with Midpoint Radial Symmetryâ€, Mechanics Based Design of Structures and Machines, Vol.42, No.4, (2014), pp.518-538.
[14] Lobontiu N, Compliant mechanisms: design of flexure hinges. CRC press, (2002).
[15] Makino E, Mitsuya T & Shibata T, “Fabrication of TiNi shape memory micro pumpâ€, Sensors and Actuators A: Physical, Vol.88, No.3, (2001), pp.256-262.
[16] MohdZubir MN & Shirinzadeh B, “Development of a high precision flexure-based micro gripperâ€, Precision Engineering, Vol.33, No.4, (2009), pp.362-370.
[17] Nisar A, Afzulpurkar N, Mahaisavariya, B & Tuantranont, A, “MEMS-based micro pumps in drug delivery and biomedical applicationsâ€, Sensors and Actuators B: Chemical, Vol.130, No.2, (2008), pp.917-942.
[18] Olsson A, Valve-less diffuser micro pumps (Doctoral dissertation, School of Electrical Engineering, Royal Institute of Technology), (1998).
[19] Peng TJ, Yang ZG, Cheng GM, Kan JW & Zeng P, “Design of double-chamber piezoelectric pump [J]â€, Optics and Precision Engineering, (2009).
[20] Qian J & Zhao, YP, “Materials selection in mechanical design for micro sensors and micro actuatorsâ€, Materials & design, Vol.23, No.7, (2002), 619-625.
[21] Stemme E & Stemme G, “A valveless diffuser/nozzle-based fluid pumpâ€, Sensors and Actuators A: physical, Vol.39, No.2, (1993), pp.159-167.
[22] Soin N & Majlis B, “Development of perfect silicon corrugated diaphragm using anisotropic etchingâ€, Microelectronic engineering, Vol.83, No.4, (2006), pp.1438-1441.
[23] Smits JG, U.S. Patent No. 4,938,742. Washington, DC: U.S. Patent and Trademark Office, (1990).
[24] Su HJ, Shi H & Yu J, “A symbolic formulation for analytical compliance analysis and synthesis of flexure mechanismsâ€, Journal of Mechanical Design, Vol.134, No.5, (2012).
[25] Shilpiekandula V & Youcef-Toumi K, Dynamic Modeling and Performance Trade-offs in Flexure-based Positioning and Alignment Systems. INTECH Open Access Publisher, (2010).
[26] Singh S, Kumar N, George D & Sen AK, “Analytical modeling, simulations and experimental studies of a PZT actuated planar valveless PDMS micropumpâ€, Sensors and Actuators A: Physical, Vol.225, (2015), pp.81-94.
[27] Teymoori MM & Abbaspour-Sani E, “Design and simulation of a novel electrostatic peristaltic micro machined pump for drug delivery applicationsâ€, Sensors and Actuators A: Physical, Vol.117, No.2, (2005), pp.222-229.
[28] Teymoori MM & Abbaspour-Sani EA, “A novel electrostatic micromachined pump for drug delivery systemsâ€, IEEE International Conference on Semiconductor Electronics, (2002), pp.105-109.
[29] Ullmann A, “The piezoelectric valve-less pump—performance enhancement analysisâ€, Sensors and Actuators A: Physical, Vol.69, No.1, (1998), pp.97-105.
[30] Van de Pol FCM, Van Lintel HTG, Elwenspoek M & Fluitman JHJ, “A thermo pneumatic micro pump based on micro-engineering techniquesâ€, Sensors and Actuators A: Physical, Vol.21, no.1-3, (1990), pp.198-202.
[31] Wu L, Yuan W, Hu N, Wang Z, Chen C, Qiu J & Li Y, “Improved piezoelectricity of PVDF-HFP/carbon black composite filmsâ€, Journal of Physics D: Applied Physics, Vol.47, No.13, (2014), pp.135-302.
[32] Woias P, “Micropumps-summarizing the first two decadesâ€, In Proc. SPIE, Vol.4560, (2001), pp.39-52.
[33] Yang EH, Yang SS, Han SW & Kim SY, “Fabrication and dynamic testing of electrostatic actuators with p+ silicon diaphragmsâ€, Sensors and Actuators A: Physical, Vol.50, No.1, (1995), pp.151-156.
[34] Yamahata C, Lotto C, Al-Assaf E & Gijs MAM, “A PMMA valve less micro pump using electromagnetic actuationâ€, Microfluidics and Nano fluidics, Vol.1, No.3, (2005), pp.197-207.
-
Downloads
-
-
How to Cite
Roopa, R., Navin Karanth, P., & M. Kulkarni, S. (2018). Design, fabrication and experimental studies of compliant flexure diaphragm for micro pump. International Journal of Engineering & Technology, 7(2.21), 66-71. https://doi.org/10.14419/ijet.v7i2.21.11838
