The invention relates to a multi-clamp type stretch forming machine which is used in the mechanical engineering field for plastic processing of a sheet type workpiece to form a curved surface.
When a workpiece is processed in a stretch forming process with a traditional stretch forming machine, the stretching action is generally provided by means of only one or two hydraulic cylinders, and the sheet material of the workpiece is substantially integrally displaced in a transverse direction at the edge clamped by the clamps. When a workpiece having a relatively large transverse curvature is processed, the distribution of stretch stress and stretch strain in the transverse direction of the sheet material becomes obviously not uniform, which results in processing defects such as departure from mold, cracking and wrinkling. In order to avoid these defects, precision requirements to the forming machines are very high, and the control systems of them have generally complex designs, thus the forming machines are very expensive. In addition, the blank material for stretch forming has generally a relatively large non-processed margin area, which results in low material usage.
An object of the invention is to overcome the above mentioned defects by providing a multi-clamp type stretch forming machine having high flexibility. In the machine, by using Pascal law in multi-cylinder hydraulic systems, process hardening characteristics of materials and law of minimum resistance, flexible control of multi-clamps is achieved in a simple way. As a result, the workpiece is more liable to be affixed to its forming mold, and the workpiece may have significantly increased material usage and stretch forming quality. Further, compared with traditional stretch forming machines, the multi-clamp type stretch forming machine of the invention can provide more uniform distribution of stretch stress and stretch strain, so that workpiece with curved surfaces can be stretch formed more uniformly. Meanwhile, manufacturing cost of the stretch forming machines can be lowered down.
For this end, the invention provides a multi-clamp type stretch forming machine, mainly comprising clamping mechanisms, stretching mechanisms and a machine frame, each clamping mechanism comprising a clamping frame, a clamper and a hydraulic clamping cylinder, wherein a row of multiple clamping mechanisms are aligned on each of opposite sides of the machine frame, the clamping frame of each clamping mechanism is provided with one or two connecting holes, and each connecting hole is coupled with one or more stretching mechanisms by means of a universal push-pull mechanism.
Optionally, in the condition that the clamping frame is provided with one connecting hole, the connecting hole is a rear connecting hole which is coupled simultaneously with at least two stretching mechanisms by means of the universal push-pull mechanism, wherein the first stretching mechanism is disposed in a horizontal orientation, and the second stretching mechanism is selectively disposed in a vertical orientation or in an oblique orientation.
Optionally, in the condition that the clamping frame is provided with two connecting holes, the connecting holes comprise a rear connecting hole and a lower connecting hole, the lower connecting hole being coupled with a vertically disposed stretching mechanism by means of a universal push-pull mechanism, and the rear connecting hole being coupled, by means of another universal push-pull mechanism, with a horizontally disposed stretching mechanism, or coupled, by means of another universal push-pull mechanism, simultaneously with a set of stretching mechanisms which comprise any combination of a horizontally disposed stretching mechanism, an obliquely disposed stretching mechanism and a vertically disposed stretching mechanism.
Optionally, each stretching mechanism comprises a hydraulic stretching cylinder, and a row of hydraulic stretching cylinders aligned in the same direction are controlled by means of one or more solenoid type reversing valves.
Optionally, each universal push-pull mechanism mainly comprises a ball-headed linkage, or mainly comprises a pivot shaft, or mainly comprises a combination of a ball-headed linkage, a pivot shaft and a link; one end of the ball-headed linkage forms a ball-shaped head, the ball-shaped head being mounted in the clamping frame or in a stretching link, directly or by means of a bearing shoe having a half-ball-shaped recess which is fit with ball-shaped surface of a retention portion of the ball-shaped head; and the opposite end of the ball-headed linkage is coupled with a corresponding link by means of a screw type mechanism or a pivot shaft.
Optionally, the ball-shaped head has a half-ball shape or a complete-ball shape; in the condition that the ball-shaped head has a half-ball shape, an elastic pad, such as a polyurethane pad, is provided at the ball-shaped head; and in the condition that the ball-shaped head has a complete-ball shape, a thrust bearing shoe having a half-ball-shaped recess is provided at the ball-shaped head.
Optionally, the ball-headed linkage comprises two ball-headed linkages which are coupled with each other symmetrically by means of a bar-like link, and thus a universal push-pull mechanism having dual ball-shaped heads is formed.
Optionally, the length of the universal push-pull mechanism is adjustable by means of a length-adjustable bar-like link.
Optionally, the pivot shaft is a solid pivot shaft or a hollow pivot shaft; and in the condition of a hollow pivot shaft, one or more steel wires or flexible steel shafts are inserted through a row of hollow pivot shafts.
Optionally, all the pivot shafts, as a whole, are substituted by one or more steel wires or flexible steel shafts inserted through the clamping mechanisms.
Optionally, each clamping mechanism in a row of multiple clamping mechanisms disposed on either side of the machine frame comprises a pair of clampers, a gap is formed between neighboring clampers, each damper comprises a clamping surface, a front edge and two front corners of which are rounded with relatively large radii, and right and left edges of the clamping surface, which are adjacent to other clampers, are also be rounded.
Optionally, the clamping surface of the clamper is a horizontal surface; or the clamping surface has a back end slightly higher than its front end; or the clamping surface has a back end which is a horizontal surface and is slightly higher than the front end of the clamping surface; or the clamping surface has a middle portion which is slightly higher than its left and right ends which are adjacent to other clampers and tapered gradually.
Optionally, the clamper has a rectangular shape, a trapezoidal shape, or a six-sided shape which is composed of a rectangle and a trapezoid; and the length of the front side of the clamping surface is equal to or less than the length of the back side of the clamping surface.
Optionally, each clamper is a biting clamper which has a clamping surface formed with many biting protrusions or a sliding-through clamper which has a clamping surface formed with several drawing ribs; and the biting clampers and the sliding-through clamper can be used in a mixed manner in a row of multiple clamping mechanisms.
Optionally, the distance between the clamping mechanisms and the stretching mechanisms on the left side of the machine frame and the clamping mechanisms and the stretching mechanisms on the right side of the machine frame is adjustable; and/or a forming mold to be used with the stretch forming machine comprises a solid mold or a multi-point adjustable digitalized mold, the forming mold having a mold base which is movable upwards; and/or a pushing-down mechanism is mounted to an upper portion of the stretch forming machine.
According to the multi-clamp type stretch forming machine of the invention, the Pascal law in a multi-cylinder hydraulic system, process hardening characteristics of materials and law of minimum resistance are used in the invention, so that, under the same level of hydraulic force of a row of hydraulic cylinders, a plurality of clamping mechanisms can move and rotate to follow the curvature of a molding surface. In this way, the load applying pattern on the workpiece is optimized, and the stretch stress and the stretch strain in the workpiece are distributed more uniformly. The mold affixing ability of the workpiece is increased, the non-processed margin area of a stretch formed piece is decreased, and the material usage and the forming quality are increased. The multi-clamp type stretch forming machine provides flexible control to a plurality of clampers by using a simple and cost efficient hydraulic system, so that the workpiece forming effect is improved with respect to traditional stretch forming machines.
The above and other features and advantages of the invention will be described in details with reference to some exemplary embodiments illustrated in the drawings, in which:
a) is an isometric view;
b) is a front view;
c) is an enlarged sectional view of a clamping mechanism shown in
d) is a front view of a universal push-pull mechanism, as used in the machine shown in
e) is a sectional view of
a) is a front view showing a rear connecting hole and a lower connecting hole of the clamping frame, each connecting hole being coupled with one or more corresponding stretching mechanisms by means of a universal push-pull mechanism comprising mainly a ball-headed linkage and two pivot shafts;
b) is an enlarged sectional view of a clamping mechanism shown in
c) is a front view showing a rear connecting hole of the clamping frame coupled with one or more corresponding stretching mechanisms by means of a universal push-pull mechanism comprising mainly a ball-headed linkage and two pivot shafts and a lower connecting hole of the clamping frame coupled with one or more corresponding stretching mechanisms by means of a universal push-pull mechanism comprising a pivot shaft;
d) is a front view showing a rear connecting hole and a lower connecting hole of the clamping frame, each connecting hole being coupled with one or more corresponding stretching mechanisms by means of a universal push-pull mechanism comprising mainly a ball-headed linkage and a pivot shaft; and
e) is an enlarged sectional view of a clamping mechanism shown in
a) is a sectional view of a ball-headed linkage, having a half-ball-shaped head at one end, mounted directly in a connecting hole of the clamping frame;
b) is a sectional view of a ball-headed linkage, having a half-ball-shaped head at one end, mounted in a connecting hole of the clamping frame by means of a bearing shoe having a half-ball-shaped recess; and
c) is a sectional view of a ball-headed linkage, having a half-ball-shaped head at one end, mounted in a connecting hole of the clamping frame by means of a bearing shoe having a half-ball-shaped recess and a head retaining ring;
a) is a sectional view showing an embodiment in which stretching links and hydraulic cylinder type links are coupled by means of a plurality of hollow pivot shafts through which a steel wire or flexible steel shaft is inserted;
b) is a sectional view showing an embodiment in which stretching links and hydraulic cylinder type links are coupled by means of a plurality of solid pivot shafts, and clamping frames and clamping linkages are coupled by means of a plurality of hollow pivot shafts through which a steel wire or flexible steel shaft is inserted;
c) is a sectional view showing an embodiment in which stretching links and hydraulic cylinder type links are coupled and clamping frames and clamping linkages are coupled respectively by means of a plurality of hollow pivot shaft through which a steel wire or flexible steel shaft is inserted; and
d) is a sectional view showing an embodiment in which stretching links and hydraulic cylinder type links are coupled and clamping frames and clamping linkages are coupled respectively by means of a steel wire or flexible steel shaft directly;
a) is a schematic view of a clamper having a height gradually reduced from its back end to its front end; and
b) is a schematic view of a clamper having, from its back end to its front end, a horizontal segment and a tapered segment;
a) is a schematic view of a rectangular clamper;
b) is a schematic view of a trapezoidal clamper; and
c) is a schematic view of a six-sided clamper having a profile formed by combination of a rectangle and a trapezoid;
1—clamping mechanism; 2—stretching mechanism; 3—machine frame; 4—universal push-pull mechanism; 5—rear connecting hole of the clamping frame; 6—hydraulic clamping cylinder; 7—clamping frame; 8—clamper coupled with a piston; 9—clamper coupled with the clamping frame; 10—hydraulic cylinder type link; 11—hollow pivot shaft; 12—stretching link; 13—ball-headed linkage, having a half-ball-shaped head at one end; 14—clamping linkage; 15—solid pivot shaft; 16—lower connecting hole of the clamping frame; 17—bar-like link; 18—ring-like polyurethane pad; 19—bearing shoe having a half-ball-shaped recess; 20—circular polyurethane pad; 21—head retaining ring; 22—ball-headed linkage, having a complete-ball-shaped head at one end; 23—thrust bearing shoe having a half-ball-shaped recess; 24—length-adjustable bar-like link; 25—steel wire or flexible steel shaft; 26—retainer; 27—sheet material; 28—mold base; 29—solid mold; 30—multi-point adjustable digitalized mold; 31—pushing-down mechanism
Now the structural details and the operation procedure of the invention will be described with reference to the embodiments shown in the drawings. Through out the drawings, elements having like or similar functions are represented by like reference numerals.
As shown in
As shown in
In the embodiment shown in
d) and 1(e) show schematic views of the universal push-pull mechanism 4, which comprises mainly a ball-headed linkage and two pivot shafts, as used in the embodiment shown in
In the illustrated exemplary embodiment
Of course, the number of the ball-headed linkage(s) and the number of the pivot shaft(s) used in the universal push-pull mechanism and the combination manner of them may be varied.
In an exemplary embodiment of the invention, the loading directions of the hydraulic stretching cylinders and the angles therebetween can be changed by changing the hydraulic forces and the strokes of the hydraulic stretching cylinders of the stretching mechanism 1, so that the position and the stretching direction of the clamping mechanism 1 are changed. In a stretch forming process, the position and the stretching direction of each clamping mechanism 1 are controlled by controlling the level of the hydraulic force and the stroke of the hydraulic stretching cylinder of the horizontal, vertical or oblique stretching mechanism, so that optimal stretching position and angle are established in the sheet material. In the illustrated exemplary embodiment, the stretching mechanism 2 and the clamping mechanism 1 are coupled by means of the universal push-pull mechanism 4, so that the clamping mechanism 1 may swing and rotate to follow the deforming tendency of the sheet material. Thus, the stretch forming machine has advantageously high flexibility.
In order to simplify the controlling system of the machine, a row of hydraulic cylinders disposed in the same orientation can be controlled by a single solenoid type reversing valve, by means of which, Pascal law in a multi-cylinder hydraulic system, process hardening characteristics of materials and law of minimum resistance are used advantageously, so that, under the action of a row of hydraulic cylinders having the same hydraulic force level, the clamping mechanisms 1 will move and rotate to follow the profile of the curved surface of the forming mold. As a result, the workpiece is likely to be affixed to the forming mold, and thus the material usage and the stretch forming quality of the workpiece can be increased.
As shown in
In the exemplary embodiment of the invention, the stretching mechanisms coupled with the clamping frame at the rear connecting hole 5 are adapted to apply a stretching force and to control the stretching direction, and the stretching mechanism coupled with the clamping frame at the lower connecting hole 16 is adapted to finely adjust the stretching direction. The stretching force and the stretching direction of the clamping mechanism 1 can be adjusted by adjusting the hydraulic force levels of the hydraulic stretching cylinders of stretching mechanisms disposed in different directions. As described above, it is contemplated that, in the exemplary embodiments, the universal push-pull mechanism for coupling the clamping frame 7 and the stretching mechanism 2 may be in the form of either a universal push-pull mechanism 4 composed of a ball-headed linkage or a universal push-pull mechanism 4 composed of a pivot shaft, only if the same stretching effect can be obtained. Of course, the number of the ball-headed linkage(s) and the number of the pivot shaft(s) used in the universal push-pull mechanism and the combination manner of them may be varied.
As shown in
It is noted that, in the exemplary embodiments of the invention, by using the universal push-pull mechanism 4, the degree of freedom of each clamping mechanism is significantly increased because the clamping mechanism is able to rotate and swing in a free way around the ball-shaped head of the ball-headed linkage of the universal push-pull mechanism 4, so that a row of multiple clamping mechanisms 1 can be aligned in a straight or curve line. Flexible control of a plurality of clamping mechanisms can also be achieved, so that the workpiece is more liable to be affixed to the forming mold in a stretch forming process, the material usage of the workpiece is significantly increased, and better workpiece forming effect can be obtained.
the universal push-pull mechanisms 4 used in the schematic view of
As shown in
e) is an enlarged sectional view of a clamping mechanism shown in
it is contemplated that, in the exemplary embodiments, the clamping frame can be coupled at the rear connecting hole 5 with a stretching mechanism, which disposed in a horizontal direction, by means of a universal push-pull mechanism, or coupled simultaneously with any combination of stretching mechanisms disposed in a horizontal direction, in an oblique orientation and in a vertical direction, only if the same stretching effect can be obtained.
The opposite end of the ball-headed linkage 13 or 22 (with reference to
b) is a sectional view of a ball-headed linkage 13, having a half-ball-shaped head at one end, mounted in a connecting hole of the clamping frame 7 by means of a bearing shoe 19 having a half-ball-shaped recess. The material for forming the bearing shoe 19 may be a bearing material such as copper or Nylon. A circular polyurethane pad 20 can be provided at a half-ball-shaped end. It is practical to adjust the level of the elastic returning force of the circular polyurethane pad 20 by adjusting the diameter and the thickness of it. Alternatively, the circular polyurethane pad 20 having a higher elastic returning force can be substituted by a ring-like polyurethane pad 18 having a lower elastic returning force according to real need.
c) is a sectional view of a ball-headed linkage 13, having a half-ball-shaped head at one end, mounted in a connecting hole of the clamping frame 7 by means of a bearing shoe 19 having a half-ball-shaped recess and a head retaining ring 21. For facilitating the swing and rotation of the ball-shaped head, a lubricant may be applied between an inner retention portion of the half-ball-shaped head and the bearing shoe 19 for lubrication.
A ring-like or circular polyurethane pad is adopted in the exemplary embodiments shown in
It is contemplated that the configuration of the steel wire or flexible steel shaft can be different from that shown in
c) is a sectional view showing an embodiment in which stretching links and hydraulic cylinder type links are coupled and clamping frames and clamping linkages are coupled respectively by means of a plurality of hollow pivot shaft through which a steel wire or flexible steel shaft is inserted. Each clamping linkage 14 is coupled with the clamping frame 7 of a corresponding clamping mechanism by means of a hollow pivot shaft 11, and each stretching link 12 is coupled with three hydraulic cylinder type links 10 by means of another hollow pivot shaft 11.
It is noted that the above embodiments are given only for illustrative, not restrictive, purpose. For example, in the technical solutions of the invention, the universal push-pull mechanism may be formed directly by several steel wire or flexible steel shafts 25.
There is a gap between neighboring dampers. The clamper comprises a clamping surface, a front edge and two front corners of which are rounded with relatively large radii. Right and left edges of the clamping surface, which are adjacent to neighboring clampers, are also be rounded with a certain radius. In this way, the sheet material of a workpiece is allowed to be displaced or expended at locations corresponding to the gaps and the rounded portions. The clamping surface is of biting type by providing many biting protrusions, so that the sheet material can be clamped tightly between each pair of clampers. Thus, during the stretch forming process, the sheet material is not allowed to move in the biting areas of the clampers.
An exemplary operation process of the multi-clamp type stretch forming machine of the invention will be described now. First, on the basis of the size and dimensions of a workpiece, the number of the clamping mechanisms 1 and the original positions of the stretching mechanisms 2 and the clamping mechanisms 1 are determined, and the shapes of the clampers are selected. Then, by adjusting the strokes of the hydraulic cylinders of the stretching mechanisms 2 disposed in different directions, the positions of a plurality of clampers are set. Then, a sheet material is inserted at its opposite edges into receiving gaps of the clampers of the clamping mechanisms 1, and the sheet material is clamped tightly by means of the clamping mechanisms 1. After the sheet material is clamped, the sheet material is pre-stretched by adjusting the strokes of the hydraulic cylinders of the horizontally disposed stretching mechanism 2. Then in a stretch step, the strokes and hydraulic forces of the hydraulic cylinders of a row of stretching mechanism 2 disposed in different directions, as a whole, are adjusted, or the upward pressure applied by the mold base 28 or the downward pressure applied by pushing-down mechanism 31 to the sheet material 27 is adjusted, so that the stretching force and the stretching direction of the clamping mechanism 1 are controlled. As a result, the clamping mechanisms 1 move and rotate to follow the curvature of the molding surface, and thus the workpiece is affixed to the mold. For increasing the mold affixing ability of the workpiece, the sequence of the movements of the vertically, horizontally and obliquely disposed stretching mechanisms 2, the upward movement of the mold base 27, the downward movement of the pushing-down mechanism 31 and the like can be adjusted. After stretch forming, the sheet material is released from the clampers by adjusting the strokes of the hydraulic cylinders of the clamping mechanisms 1.
According to the multi-clamp type stretch forming machine of the invention, each clamping mechanism is provided with one or two connecting holes where the clamping mechanism is coupled with one or more stretching mechanisms by means of a universal push-pull mechanism. Further, the Pascal law in a multi-cylinder hydraulic system, process hardening characteristics of materials and law of minimum resistance are used in the invention, so that, under the same level of hydraulic force of a row of hydraulic cylinders, a plurality of clamping mechanisms can move and rotate to follow the curvature of a molding surface. In this way, the load applying pattern on the workpiece is optimized, and the stretch stress and the stretch strain in the workpiece are distributed more uniformly. The mold affixing ability of the workpiece is increased, the non-processed margin area of a stretch formed piece is decreased, and the material usage and the forming quality are increased. The multi-clamp type stretch forming machine provides flexible control to a plurality of clampers by using a simple and cost efficient hydraulic system, so that the workpiece forming effect is improved compared with traditional stretch forming machines.
The embodiments of the invention as described above are illustrative, not restrictive. The features of the above embodiments can be changed, combined or modified in any suitable manners within the scope and spirit of the invention, and the scope of protection of the invention is intended to cover all these changes, combinations and modifications.
Number | Date | Country | Kind |
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2009 1 0217701 | Oct 2009 | CN | national |
2010 1 0266441 | Aug 2010 | CN | national |
2010 1 0273822 | Sep 2010 | CN | national |
2010 1 0273846 | Sep 2010 | CN | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CN2010/077581 | 10/8/2010 | WO | 00 | 4/9/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/041984 | 4/14/2011 | WO | A |
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Number | Date | Country | |
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20120198904 A1 | Aug 2012 | US |