This disclosure pertains to a shaft straightening or tube straightening apparatus that performs accurate measurements of the linear profile of a metal tube, and then corrects small and large deviations of the tube profile from the ideal centerline along the length of the tube. More specifically, the present disclosure pertains to an automated tube straightening apparatus that is operable to accurately measure a linear profile of a metal tube positioned in the apparatus. The tube is rotated in the apparatus to locate a pair of low points in the tube profile and a high point of the tube profile. The tube is supported in the apparatus at the pair of low points and the high point of the tube is then deflected beyond the yield point of the metal of the tube to permanently distort the tube and correct the tube's profile.
Aluminum and stainless steel shafts and/or tubes ranging from 1-3½ inches in diameter, and 29-169 inches in length, are often heat treated which typically warps the tube in one or more planes. Deformation of the tubes can range in form from a simple bow along the tube length, to a complex spiral of the tube length. The span of a deformation can range from 4 inches of the overall tube length, to the entire length of the tube. Multiple deformations can occur in each tube.
Corrections to the tube deformations or “run out” are currently made manually with a dial indicator, a hand press, and two supporting fixtures for the tube which are moved along the tube length as needed. Corrections are made by profiling the tube length and determining where corrections are needed, and then strategically positioning the tube on the supporting fixtures where the ram of the hand press can be used to deflect the tube to decrease the tube run out and straighten the tube profile. The operator of the hand press positions the ram of the press at the tube high point and then extends the ram a distance to deflect the tube and correct the measured run out of the tube high point by anticipating the spring back of the tube after the force of the ram is removed. An acceptable run out is 5/1000 of an inch over the entire length of the tube. This manual process of correcting tube deformations is labor intensive and requires experienced operators to straighten tubes. This process is a major bottleneck in the aerospace industry manufacturing tubes used for drive shafts and actuator rods.
The shaft or tube straightening apparatus of the invention provides an operator controlled or fully automated system that simulates the manual tube straightening operation.
The apparatus comprises a frame that supports the apparatus in an upright orientation. The frame has a centrally located open area that is dimensioned to receive a length of shaft or tubing to be straightened by the apparatus.
A plurality of holding cylinders or holding devices are supported on the frame. The holding devices are arranged side-by-side on the frame beneath the frame open area. Each of the holding devices has a rod with an end surface that is configured as a holding fixture for holding a portion of a tube engaged by the end surface. Each of the rods is movable in reciprocating movements along an axis of the rod between an extended position of the rod from the holding device, and a retracted position of the rod relative to the holding device. In the rod extended position the rod end surface is moved into the frame open area to engage with a tube that has been positioned in the open area and to support the tube on the rod end surface.
The apparatus also comprises a plurality of actuator ram cylinders or actuator devices that are supported on the frame. The actuator devices are positioned side by side on the frame on an opposite side of the frame open area from the plurality of holding devices. Each of the actuator devices has a ram that is movable in reciprocating movements along an axis of the ram between an extended position of the ram from the actuator device, and a retracted position of the ram relative to the actuator device. Each ram has an end surface configured for engaging and exerting a force against an area of the tube positioned in the frame open area. In the extended position of the ram, the ram end surface is moved into the frame open area to engage with a tube that is supported on at least two of the end surfaces of holding device rods that have been extended into the open area. The extended ram end surface engaging with the tube supported in the frame open area bends the tube. As the ram end surface bends the tube it moves the portion of the tube being bent a distance through the frame open area.
A plurality of proximity sensors are also supported on the frame. The proximity sensors are positioned side by side adjacent the plurality of actuator devices on the opposite side of the frame open area from the plurality of holding devices. Each of the proximity sensors is operable to sense the distance the tube is moved through the frame open area as the tube is being bent by the actuator device ram engaging the tube.
The apparatus also includes a rotation device supported on the frame. The rotation device is positioned adjacent the frame open area and between the plurality of holding devices and the plurality of actuator devices. The rotation device is connectable to the tube positioned in the frame open area and is operable to rotate the tube in the open area.
The apparatus also includes a controller that communicates with the plurality of holding devices, the plurality of actuator devices, the plurality of proximity sensors and the rotation device. The controller includes an operator screen or display screen communicating with the controller. The display screen is operable to display a visual indication of the distance sensed by each of the proximity sensors to the portion of the tube in the frame open area that is opposite the proximity sensor.
In operation of the apparatus, a length of tube to be straightened by the apparatus is first positioned in the frame open area. The rods of the plurality of holding devices are then extended to precision hard stops of the holding devices that control the extended positions of the rod. The length of tube is supported on the rod end surfaces. The rotation device is connected to an end of the tube to hold the tube against rotation in the frame open area. The plurality of proximity sensors are activated to float on the surface of the tube opposing the proximity sensors. Each of the proximity sensors senses its distance from the tube surface, and the tube profile in one plane is measured from data signals provided by the proximity sensors to the controller. The proximity sensor data is displayed on the display screen. From the displayed data the tube is rotated until the maximum error in the tube's profile is detected. The best supporting holding devices are identified for supporting the tube at two low points of the tube profile for the desired correction of the tube profile. All of the other holding device rods between the selected two supporting rods are retracted to allow for deflection of the tube between the two supporting rods.
The display of the sensor data on the displays screen also identifies a high point in the tube profile. The ram of the actuator device at the high point is then extended from the actuator device to engage against the profile high point of the tube. The engagement of the ram end surface against the tube high point begins to bend the tube and move the tube a distance through the frame open area. The distance the tube is moved through the frame open area as the ram end surface bends the tube is sensed by the proximity sensor associated with the actuator device of the extended ram. The extension of the ram from the actuator device is controlled to bend the portion of the tube at the tube high point and move the portion of the tube a specified distance through the frame open area based on the run out of the tube profile. The bending of the tube is tracked by the controller from the proximity sensor data. When the desired deflection distance of the tube is achieved, the actuator device ram is retracted. The resulting tube profile is evaluated by the plurality of proximity sensors and the controller and the profile correction process is applied again if needed. Once a desired correction of the tube profile is achieved, the rotation device is activated to rotate the tube in the frame open area to identify the next deformation of the tube that is to be corrected using the same procedure. The process is repeated until the run out of the tube is within acceptable specifications.
Further features of the apparatus and associated method are set forth in the following detailed description of the apparatus and in the drawing figures.
The apparatus 10 comprises a frame 12 that supports the apparatus in a generally upright orientation. The frame 12 shown in
A plurality of holding devices 18, 20, 22, 24, 26, 28, 30 are supported on the frame 12. In the exemplary embodiment of the apparatus 10 shown in
As represented in
The apparatus 10 also comprises a plurality of actuator devices 32, 34, 36, 38, 40, 42, 44 that are supported on the frame 12. In the exemplary embodiment of the apparatus 10 represented in
In the exemplary embodiment represented in
Referring back to
A plurality of proximity sensors 46, 48, 50, 52, 54, 56, 58 are also supported on the frame 12. The proximity sensors are capable of precise, accurate measurements, for example, to about 0.0001 inches. For example, the proximity sensors could be inductive proximity sensors or other equivalent types of sensors. The proximity sensors 46, 48, 50, 52, 54, 56, 58 are positioned adjacent the respective actuator devices 32, 34, 36, 38, 40, 42, 44 and on opposite sides of the frame open area 14 from the respective holding devices 18, 20, 22, 24, 26, 28, 30. As represented in
The apparatus 10 also includes a rotation device 60 supported on the frame 12. As represented in
The apparatus also includes a programmable logic controller 66 that communicates with the plurality of holding devices 18, 20, 22, 24, 26, 28, 30, the plurality of actuator devices 32, 34, 36, 38, 40, 42, 44, the plurality of proximity sensors 46, 48, 50, 52, 54, 56, 58 and the rotation device 60. The controller 66 includes an operator screen or display screen 68 communicating with the controller. The display screen 68 is operable to display a visual indication of the distance sensed by each of the proximity sensors 46, 48, 50, 52, 54, 56, 58 to the portion of the tube 16 in the frame open area 14 that is opposite the proximity sensor. This enables the display screen 68 to provide a visual indication of the profile of the tube 16 in the particular orientation of the tube held by the rotation device 60 in the frame open area 14. The location of the tube's upper surface or the surface directed toward the proximity sensors is displayed, providing a visual indication of the location of the tube's upper surface above the ideal zero reference. The controller 66 also includes a pair of joysticks 72, 74 on opposite sides of the controller. One of the joysticks 72, the left joystick shown in
In operation of the apparatus 10, the length of tube 16 to be straightened by the apparatus is first positioned in the frame open area 14. One end of the tube 16 is firmly grasped by the clamp 62 of the rotation device 60. The holding device rods 18r, 20r, 22r, 24r, 26r, 28r, 30r are then extended by an operator operating the program logic controller 66. The rods are extended to the precision hard stops of the holding devices 18, 20, 22, 24, 26, 28, 30. These position the rod distal end surfaces 18s, 20s, 22s, 24s, 26s, 28s, 30s in substantially a same plane. The length of tube 16 is supported on at least some of the end surfaces of the rods due to its warped profile.
The operator at the operator's screen 68 then activates the rotation device 60 to rotate the tube 16 in the frame open area 14. As the tube 16 is rotated by the rotation device 60, each of the proximity sensors 46, 48, 50, 52, 54, 56, 58 senses the distance of the portion of the tube surface opposite the sensor and produces a signal that is representative of this distance. These signals are transmitted to the programmable logic controller which then controls the display screen 68 to display a visual representation of the distance of each proximity sensor to the portion of the tube surface opposite the sensor. The operator, using the left joystick 72 of the controller 66 controls a translation of the tube 16 and rotation of the tube in the frame open area 14 until a desired warped profile of the tube surface opposite the proximity sensors is displayed on the display screen 68.
The display screen also displays a sensed distance representation 86 from the proximity sensor 50 that is opposite the high point of the tube profile. Using the right joystick 74, the operator at the screen 68 then selects the actuator device 36 that is opposite the highest portion of the tube profile sensed by the proximity sensor 50. This is represented in
The resulting profile of the tube 16 is then evaluated from the data received by the programmable logic controller 66 from the proximity sensors 46, 48, 50, 52, 54, 56, 58 and the correction process is applied again if needed. Once the desired correction in the tube profile is achieved, the programmable logic controller 66 is operated by the operator to again activate the rotation device 60 to rotate the tube 16 in the frame open area 14 until the next deformation of the tube 16 is identified and corrected using the same procedure. This process is repeated until the run out of the tube 16 is within specifications.
Although the apparatus described herein and its method of use have been described by reference to a particular embodiment of the apparatus, it should be understood that modifications and variations to the apparatus and method could be made without departing from the intended scope of the claims appended hereto.
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