1. Technical Field
The present disclosure generally relates to detecting devices, and particularly to a dynamic balance detecting device for rotors.
2. Description of the Related Art
Rotor vibrations affect the lifetime and machining accuracy of machines. Non-uniform distributions of mass about the spin axis, installation tolerance can cause vibrations when a rotor rotates. An unbalanced position and amount of the unbalance of the rotor can be measured by dynamic balance detecting devices. The unbalance of the rotor is lowered by adding or reducing balancing weight block at appropriate positions. However, known dynamic balance detecting devices have complex structures and vibrate significantly when in use, which affects accuracies of the measurements and regulating.
Therefore, there is room for improvement within the art.
The components in the drawings are not necessarily drawn to scale, the emphasis instead being placed upon clearly illustrating the principles of the present disclosure. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.
The FIGURE shows an assembled, isometric view of an embodiment of a dynamic balance detecting device.
The disclosure is illustrated by way of example and not by way of limitation in the figures of the accompanying drawings in which like references indicate similar elements. It should be noted that references to “an” or “one” embodiment in this disclosure are not necessarily to the same embodiment, and such references mean “at least one.”
The FIGURE shows a dynamic balance detecting device 100 for detecting and regulating a dynamic balance of a rotor 200. The dynamic balance detecting device 100 includes a support frame 10, a platform 20, a pillar 30, an installation base 40, a main shaft 50, a vibration sensor 60, a rotation sensor 70, a dynamic measuring tester 80, and a controller 90. The platform 20 is supported on the support frame 10. The pillar 30 is connected substantially perpendicularly to the platform 20. The main shaft 50 is connected to the pillar 30 by the installation base 40. The rotor 200 is assembled to the main shaft 50. The main shaft 50 is capable of rotating the rotor 200 at a high speed. The vibration sensor 60 is located on a surface of the main shaft 50 for detecting vibration of the main shaft 50. The rotation sensor 70 is connected to the pillar 30 and is adjacent to the main shaft 50 for detecting a rotation speed of the main shaft 50. The dynamic measuring tester 80 is electrically connected with the vibration sensor 60 and the rotation sensor 70. The dynamic measuring tester 80 is configured for receiving and displaying vibration data obtained by the vibration sensor 60 and receiving rotation data obtained by the rotation sensor 70 in real time to analyze and determine whether dynamic balance of the rotor is within a predetermined tolerance,. Therefore, adjustment of adding or reducing balancing weight in corresponding positions for the rotor 200, is obtained and displayed by the dynamic measuring tester 80 required if the dynamic balance of the rotor is not within a predetermined tolerance. The controller 90 is electrically connected to the main shaft 50, the vibration sensor 60, the rotation sensor 70, and the dynamic measuring tester 80. In one embodiment, the platform 20 and the pillar 30 are made of marble for reducing vibration.
The support frame 10 includes a frame body 11 and four movable foot assemblies 13 separately assembled to the frame body 11. Each movable foot assembly 13 includes a connection base 131, a rolling wheel 133, and an assist foot 135. The connection base 131 is fixed to a bottom portion of the frame body 11. The rolling wheel 133 is rotatably connected to the connection base 131 for conveniently moving the dynamic balance detecting device 100. The assisting foot 135 is connected to the connection base 131 for support the frame body 11.
The pillar 30 is substantially L-shaped. The pillar 30 includes a fixing portion 31, an installation portion 33, and two reinforcing portions 37. One end of the fixing portion 31 is connected to the platform 20. The installation portion 33 extends substantially perpendicularly from another end of the fixing portion 31. The two reinforcing portions 37 are fixed to the platform 20 and opposite sides, respectively, of the fixing portion 31 to mount the fixing portion 31 to the platform 20. Each reinforcing portion 37 includes a first mounting block 371, a second mounting block 373, and two third mounting blocks 375. The first mounting block 371 is fixed to the platform 20. The second mounting block 37 is fixed to the fixing portion 31 and connected substantially perpendicularly to the first mounting block 375. A shape of each of the two third mounting blocks 375 is substantially a right triangle. The two third mounting blocks 375 are connected between two end edges, respectively, of the first mounting block 371 and the second mounting block 373, such that two right angle edges of the third mounting blocks abut the fixing portion 31 and the platform 20. The two third mounting blocks 375 are substantially parallel to each other.
The installation base 40 is substantially sleeve-like and defines a penetrating hole 41 therethrough. The installation base 40 is fixed to an end of the installation portion 33.
The main shaft 50 is received through the penetrating hole 41 and is fixedly connected to the installation base 40. The main shaft 50 is substantially parallel to the fixing portion 31. The main shaft 50 includes a driving portion 51 and a rotary portion 53 connected to the driving portion 51. Vibrations produced by the main shaft 50 are absorbed by the pillar 30 and the platform 20. The rotary portion 53 clamps the rotor 200 and is rotated at a high speed by the driving portion 51.
The vibration sensor 60 is located on a surface of the rotary portion 53 for detecting vibrations of the main shaft 50. The rotation sensor 70 is located adjacent to a side of the main shaft 50 for detecting the rotation speed of the main shaft 50. In the illustrated embodiment, the rotation sensor 70 is a laser sensor.
The dynamic measuring tester 80 includes a testing body 81 and a display screen 83 positioned on the main body 81. The testing body 81 is electrically connected with the vibration sensor 60 and the rotation sensor 70. The testing body 81 receives, analyzes, and calculates vibration data obtained by the vibration sensor 60 and rotation data obtained by the rotation sensor 70. The dynamic measuring tester 80 determines whether the rotor 200 is dynamically balanced as desired. If the rotor 200 is not dynamically balanced, the dynamic measuring tester 80 continuously calculates, and the adjustment data in corresponding positions for the rotor 200 is obtained. The display screen 83 displays the vibration data, the rotation speed data, and the regulating data received and obtained by the testing body 81 in real time. The controller 90 controls the main shaft 50, the vibration sensor 60, the rotation sensor 70, and the dynamic measuring tester 80.
In use, the rotor 200 is clamped by the rotary portion 53. A mark (not shown) is marked on the main shaft 50 for the rotation sensor 70 to obtain the rotation speed of the main shaft 50. The main shaft 50 rotates the rotor 200. The vibration sensor 60 detects the amount of vibration of the main shaft 50 and sends the detected amount to the dynamic measuring tester 80. The rotation sensor 70 detects the rotation speed of the main shaft 50 and sends the detected rotation speed to the dynamic measuring tester 80. The dynamic measuring tester 80 receives, analyzes, judges, and calculates vibration data obtained by the vibration sensor 60 and rotation data obtained by the rotation sensor 70, so that the adjustment is obtained and displayed by the dynamic measuring tester 80. An operator regulates the rotor 200 according to the regulating amount.
The dynamic balance detecting device 100 is a simple structure and convenient to operate. The platform 20 and the pillar 30 are made of marble for reducing vibration. The outer wall of the driving portion 51 is snugly engaged with the inner wall of the penetrating hole 41, then vibrations produced by the main shaft 50 rotating are adsorbed by the pillar 30 and the platform 20. Therefore, detecting and regulating accuracy of the dynamic balance detecting device 100 is improved.
In other embodiments, the support frame 10 can be omitted, the platform 20 can be supported on floor or the like. The installation base 40 can be omitted, and the driving portion is directly fixed on the installation portion 33.
While the present disclosure has been described with reference to particular embodiments, the description is illustrative of the disclosure and is not to be construed as limiting the disclosure. Therefore, various modifications can be made to the embodiments by those of ordinary skill in the art without departing from the true spirit and scope of the disclosure, as defined by the appended claims.
Number | Date | Country | Kind |
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2013100896202 | Mar 2013 | CN | national |