It has been designed and analyzed the low cost viscometer using falling ball method, the sample analyzed is glycerin fluid at 20oC. Two optocoupler circuits have been used as time measurement system of falling ball between two references point, light source used was infrared laser diode. The computer acquisition system use serial communication and it has been perfectly made and characterized. The velocity measurement system has 0.75 x 10-1 s resolution, but the resolution of integrated system both of hardware and acquisition software, is about 10-1 s. The theoretical viscosity value has been calculated and simulated to abtain the absolute viscosity value. This simulation results have been analyzed and compared with the experiment results. The correction factor for velocity calculation has been discussed and gave the optimum value of velocity correction factor (0.4425), regarding to the dimension of tube and ball used in this research. Based on the experiment, the viscosity of glycerin obtained was 1418.0309±1.6157 mPa.s., this value was with similar with the literatures and has a 0.57% of accuracy error (ε0).

Brizard, M., Megharfi, M., Fredier, C & Mahe, E. 2005. Design of a high precision falling ball viscosimeter, Review of Scientific Instruments 76 (2).

Dorsey, N.E. 1940. Properties of ordinary water substance. New York press.

Francis, Alfred W. 1933. Wall effect in falling ball method for viscosity. Physics 4, 403.

Fujita, Yoshitaka, Naoki Kuramoto, Yasumitsu Kurano & Kenichi Fujii. 2003. An absolute measurement of the viscosity by the falling ball method. Proceeding of 14th Conference on the Properties of Water and Steam in Kyoto.

Fujita, Yoshitaka, Naoki Kuramoto, Yasumitsu Kurano & Kenichi Fujii. 2005. A study on an absolute measure- ment of the viscosity by the Falling Ball Method for a primary viscosity standard : development of a velocity measurement system for falling ball. Thermophysics Jour- nal. Volume 26 Page 430-432.

Gottlieb & Moshe. 1979. Zero-shear-rate viscosity measure- ments for polymer solutions by falling ball viscometry. Journal of Non-Newtonian Fluid Mechanics. Volume 6, Issue 2, 1979, Pages 97-109.

Han, Aijie, Weiyi Lu, K Puryamutula, Xi Chen & Falgun B Surani. 2008. Effective viscosity of glycerin in a nanoporous silica gel. Journal of Applied Physics. 104. 124908.

Hinrichs, Richard, J & Judy Thuen. 1985. Method for determining resin viscosity with ultrasonic waves. United States Patent. Number 4559810, 24 December.

Leont’ev, A.P & Vakhrushev, I.A. 1976. Experimental determination of effective viscosity of fluidized beds by falling-ball method. Chemistry and Technology of Fuels and Oils. Volume 12, Number 4, 294-297.

Lommatzsch T, Megharfi, M, Mahe, E & Devin, E. 2001. Conceptual study of an absolute falling-ball viscometer. Metrologia. 38 531.

Thibodeau, & Len. 2004. Measuring viscosity of pastes. American Laboratory News. Volume: June.

Truell, R., Elbaum, C & Chick, B. 1969. Ultrasonic methods in solid state physics. Academic Press, New York and London.

Walters, K & Jones, W. N. 1996. Measurement of Viscosity. Instrumentation Reference Book. Butterworth – Heineman, Oxford.

Warsito, Sri Wahyu Suciyati & Andriyanto. 2009. Analisis pemanfaatan mikrokontroler AT89C51 sebagai pemroses system pencacah putaran objek berputar : prospektif sebagai alat uji kelelahan oli. Proseding Seminar Nasional Sains MIPA dan Aplikasinya. 1,() 453 – 462.

Warsito, Sri Wahyu Suciyati & Romi Akbar. 2010. Transduser Ultasonik Tipe MA40E7R/5 Waterproof untuk mengukur viscositas fluida. In press.