Patent Application
20080041175
Referring to the drawings, and initially to
The screw shaft 10 includes two end portions 12 for being supported on various supporting objects or members or machines (not shown) each having an outer peripheral shoulder 13 formed therein for forming or defining a diameter reduced end segments 14, and includes a cylindrical or longitudinal bore 15 provided therein and formed through the screw shaft 10 and the two end portions 12 or the diameter reduced end segments 14 of the screw shaft 10. It is preferable that the cylindrical or longitudinal bore 15 of the screw shaft 10 includes a uniform inner diameter “d” (
However, alternatively, as shown in
The screw shaft 10 further includes a first inserted material or member 30 (
The first inserted member 30 includes an E/ρ value greater than the E/ρ value of the further inserted members 31, 32 which is preferably greater than the E/ρ value of the plugs or inserted terminals 33 that are disposed or engaged in the diameter reduced end segments 14 of the screw shaft 10, in which E: Young's modulus or longitudinal elastic coefficient (kgf/cm2), and ρ:specific weight (kg/cm3).
The maximum numbers Nc of revolutions of the screw shaft 10 may be obtained from the equation or formula:
Nc=60λ2/2πL2×{ExIxg/(ρ×A)}1/2,
in which λ: boundary parameter, I: inertia momentum, g: gravitational acceleration, and A: cross section of the screw shaft 10.
The maximum numbers Nc of revolutions of the screw shaft 10 is proportional to the value of {E/ρ}1/2, and thus the maximum numbers Nc of revolutions of the screw shaft 10 may be suitably increased when the materials for making the screw shaft 10 include a greater {E/ρ}1/2 value, or when the screw shaft 10 and the materials or members 30-33 engaged into the screw shaft 10 include a greater {E/ρ}1/2 value, or when the materials or members 30-33 for engaging into the screw shaft 10 include a greater {E/ρ}1/2 value.
Accordingly, in the middle or intermediate portion 16 of the screw shaft 10, the amplitude of the vibration may be the greatest or may be greater than the other portions, such as the two end portions 12 and/or the diameter reduced end segments 14 of the screw shaft 10, and the provision and the engagement of the stronger first inserted material or member 30 (having greater {E/ρ}1/2 value) into the middle or intermediate portion 16 of the cylindrical or longitudinal bore 15 of the screw shaft 10 may suitably increase the maximum numbers Nc of revolutions of the screw shaft 10, and the further weaker inserted materials or members 31, 32 (having smaller {E/ρ}1/2 value) may be disposed or engaged in the two end portions 12 of the screw shaft 10 where the amplitude of the vibration may be relatively smaller.
As shown in
The provision or the engagement of the plugs or inserted terminals 33 in the diameter reduced end segments 14 of the screw shaft 10 may position and retain the materials or members 30-32 in the cylindrical or longitudinal bore 15 of the screw shaft 10 and may prevent the materials or members 30-32 from being disengaged from the cylindrical or longitudinal bore 15 of the screw shaft 10. The materials or members 30-32 and the plugs or inserted terminals 33 are preferably solidly secured together with adhesive materials, such as silicone materials.
Accordingly, the screw shaft device in accordance with the present invention includes an improved cushioning structure for suitably dissipating vibration and for increasing the allowable rotating velocity of the ball screw.
Although this invention has been described with a certain degree of particularity, it is to be understood that the present disclosure has been made by way of example only and that numerous changes in the detailed construction and the combination and arrangement of parts may be resorted to without departing from the spirit and scope of the invention as hereinafter claimed.
