Journal of Engineering Sciences

Author(s): Lishchenko N. V.¹, Larshin V. P.²

Affilation(s):
¹ Odessa National Academy of Food Technologies, 112 Kanatna St., Odessa, 65039, Ukraine
² Odessa National Polytechnic University, 1 Shevchenka Av., Odessa, 65044, Ukraine

^*Corresponding Author’s Address: [email protected]

Issue: Volume 5; Issue 1 (2018)

Dates:
Paper received: December 29, 2017
The final version of the paper received: February 3, 2018
Paper accepted online: March 5, 2018

Citation:
Lishchenko, N. V., Larshin, V. P. (2018). Profile gear grinding temperature reduction and equalization. Journal of Engineering Sciences, Vol. 5(1), pp. A1–A7, doi: 10.21272/jes.2018.5(1).a1

DOI: 10.21272/jes.2018.5(1).a1

Research Area: MANUFACTURING ENGINEERING: Machines and Tools

Abstract. The profile gear grinding modes definition technique is developed to provide the uniform residual temperatures after heating and subsequent cooling which predetermine uniform thermal deformations on periphery of a cogwheel when grinding. The initial basis for this is a possibility to determine the gear grinding temperature both on the heating and cooling stages and, besides, it is may be also a choice of the operation cycle structure with and without the working stroke omission. In the interval of the profile gear grinding modes, two variants of the gear grinding working cycle structure with reciprocating displacement of the grinding wheel are considered using the simulation method with an omission and without one of the working stroke. Certain combinations of mode parameters are found in the range of their possible values at which the combination of heating and cooling leads to the lowest residual surface temperature both during and after working stroke.

Keywords: profile gear grinding, gear grinding temperature, heating stage, cooling stage, cycle structure, working stroke, temperature.

References:

1. Kalashnikov, S. N. et al. (1990). Proizvodstvo zubchatykh koles: Handbook. Moscow, Mashinostroyeniye [in Russian].
2. Lishchenko, N. V. (2016). Opredeleniye intensivnosti zuboshlifovaniya na osnove analiticheskogo uravneniya evol’venty. Suchasni tekhnologii v mashinobuduvanni, Issue 11 [in Russian].
3. Dekapolitov, M. I. (2011). Povysheniye effektivnosti profil’nogo zuboshlifovaniya tsilindricheskikh koles putem rascheta pa-rametrov staticheskoy naladki: Ph.D. thesis. Specialties 05.02.07 – Tekhnologiya i oborudovanie mekhanich. i fiziko-tekhnologicheskoy obrabotki; 05.02.08 – Tekhnologiya mashinostroyeniya. Moscow.
4. Nishimura, Yu., Katsuma, T., Ashizawa, Y., Yanase, Y., Masuo, K. (2008). Gear grinding processing developed for high-precision gear manufacturing. Mitsubishi Heavy Industries, Ltd. Technical Review, Vol. 45, No. 3, 33–38.
5. Carslaw, H. S., Jaeger, J. C.(1959). Conduction of heat in solids (2nd ed.). London, Oxford University Press.
6. Larshin, V. P. (1999). Tekhnologiya mnogonitochnogo rez’boshlifovaniya pretsizionnykh khodovykh vintov. Proceedings of Odessa National Polytechnic University, Odessa, Issue 2(8), 87–91 [in Russian].

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