0,5 dwR VR 2-3) w₁ = 2π n; VR - 0.5 d WR = 0; VR + 0.5 d WR = (0.5 D + d) wa; 0.5 (D+ d) Wcage = 0.5 d WR → NR = 0.5 WR/ π = n (0.5 D/d + 1); ncage = 0.5 Wcage/ π = n (0.5 D + d)/(D + d) WR VR VR 0,5 d wr 2-3) A cylindrical roller bearing consists of the inner ring with race diameter D, the outer ring, the cylindrical rolling elements with diameter d and the cage which keeps the distance between the rolling elements and is transported by them. Determine the rotational frequencies of the rolling elements NR and the cage Ncage, when the inner ring is static and the outer ring is moving with n! Assumption: Rolling (no sliding) in the contacts of the rolling elements with the inner and outer ring.

0,5 dwR VR 2-3) w₁ = 2π n; VR - 0.5 d WR = 0; VR + 0.5 d WR = (0.5 D + d) wa; 0.5 (D+ d) Wcage = 0.5 d WR → NR = 0.5 WR/ π = n (0.5 D/d + 1); ncage = 0.5 Wcage/ π = n (0.5 D + d)/(D + d) WR VR VR 0,5 d wr 2-3) A cylindrical roller bearing consists of the inner ring with race diameter D, the outer ring, the cylindrical rolling elements with diameter d and the cage which keeps the distance between the rolling elements and is transported by them. Determine the rotational frequencies of the rolling elements NR and the cage Ncage, when the inner ring is static and the outer ring is moving with n! Assumption: Rolling (no sliding) in the contacts of the rolling elements with the inner and outer ring.

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter15: Oscillations

Section: Chapter Questions

Problem 26P: A tire has a tread pattern with a crevice every 2.00 cm. Each crevice makes a single vibration as...

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