Synthesising a Four-Bar Linkage for an Assembly Line Featuring Intermittent Drag Chain Motion
| Authors: Khalturin M.A. | Published: 02.08.2018 |
| Published in issue: #4(121)/2018 | |
| Category: Mechanical Engineering and Machine Science | Chapter: Machine Science | |
| Keywords: assembly line, intermittent motion, four-bar linkage, payload increase coefficient, drag chain halt deviation factor | |
We developed a new assembly line design featuring intermittent drag chain motion by means of a drive comprising a four-bar linkage. We propose a method of calculating basic geometrical parameters of the device. We implemented the four-bar linkage system using a computer, making it possible to determine the following parameters of the mechanism: crank, coupler and rocker lengths; initial crank position; rocker configuration angle. We consider a method of selecting optimum mechanism parameters. The mechanism structure designed meets the following criteria: satisfying Grashofs crank existence condition, ensuring minimum loads in kinematic pairs and matching the rocker motion curve to the actual function of the mechanism. The author suggests two parameters for estimating the efficiency of the mechanism: payload increase coefficient and drag chain halt deviation factor
References
[1] Timofeev G.A., ed. Teoriya mekhanizmov i mekhanika mashin [Theory of mechanisms and machinery mechanics]. Moscow, Bauman MSTU Publ., 2009. 688 p.
[2] Root V.G., Polyakov V.K., Rudnev A.V., Shim V.V. Konveyer s preryvistym dvizheniem tyagovogo organa [Intermittent motion conveyor]. Patent RF 2108278. Appl. 31.12.1996, publ. 10.04.1998.
[3] Timirgazin M.R. Mekhanizm preryvistogo dvizheniya [Intermittent motion mechanism]. Patent RF 2091642. Appl. 27.12.1994, publ. 27.09.1997.
[4] Maslennikov R.S., Marfin D.G. Konveyer s preryvistym dvizheniem tyagovogo organa [Intermittent motion conveyor]. Patent RF 2416560. Appl. 26.08.2009, publ. 20.04.2011.
[5] Timofeev G.A., Barbashov N.N., Tsibrovskiy A.N. Designing the intermittent motion mechanism on the basis of wave gear with the internal deformation waves generator. Vestn. Mosk. Gos. Tekh. Univ. im. N.E. Baumana, Mashinostr. [Herald of the Bauman Moscow State Tech. Univ., Mechan. Eng.], 2016, no. 2, pp. 113–124 (in Russ.). DOI: 10.18698/0236-3941-2016-2-113-124
[6] Corves B. Servo drives, mechanism simulation and motion profiles. In: New trends in mechanism science. Springer, 2010. P. 147–155.
[7] Artobolevskiy I.I. Mekhanizmy v sovremennoy tekhnike. T. 3. Rychazhno-kulachkovye, rychazhno-zubchatye, rychazhno-khrapovye, rychazhno-klinovye i vintorychazhnye mekhanizmy. Mekhanizmy s gibkimi i uprugimi zvenyami [Mechanisms in modern technique. Vol. 3. Lever-cam, lever-toothed, lever-ratchet, lever-wedge and screw-lever mechanisms. Mechanisms with flexible and elastic links]. Moscow, Nauka Publ., 1979. 416 p.
[8] Pozhbelko V.I. Sposob i mekhanizm Pozhbelko V.I. dlya vosproizvedeniya vrashcheniya s ostanovkami [VI. Pozhbilko method and mechanism for representation of intermittent motion]. Patent RF 2249133. Appl. 25.07.2003, publ. 27.03.2005.
[9] Shagiakhmetov A.I. Sozdanie i osnovy proektirovaniya reguliruemykh zubchato-rychazhnykh privodov periodicheskogo dvizheniya na osnove ellipticheskikh zubchatykh koles. Avtoref. diss. kand. tekh. nauk [Development and basis of designing adjustable lever-toothed drives of periodic motion on the basis of elliptic gears. Abs. kand. tech. sci. diss]. Chelyabinsk, 2011. 19 p. (in Russ.).
[10] Dorić J., Klinar I., Dorić M. One approach for modelling intermittent motion mechanism with noncircular gears. Machine Design, 2011, vol. 3, no. 2, pp. 121–126.
[11] Artobolevskiy I.I. Teoriya mekhanizmov i mashin [Mechanism and machine theory]. Moscow, Alyans Publ., 2011. 640 p.
