US3472057A

US3472057A - Bending press

Info

Publication number: US3472057A
Application number: US536686A
Authority: US
Inventors: George J Persico; Luther R Steele
Original assignee: Walker Manufacturing Co
Current assignee: Walker Manufacturing Co
Priority date: 1966-03-23
Filing date: 1966-03-23
Publication date: 1969-10-14
Anticipated expiration: 1986-10-14

Description

Oct: 14, 1969 G. J. PERSICO" ET AL 3,472,057

BENDING PRESS Filed March 23, 1966 5 Sheets-Sheet 1 "21 if 4 J 2 FIEI]- .L-

INVENTORg. 6'60? e Jt'y enszza 5 Sheets-Sheet 5 Oct. 14, 1969 J, p s c ET AL BENDING PRESS Filed March 23, 1966 W W 1 M A 1 F. m w 1 J J r 7 4 X L 5 Z 1 1w 7 w u.q Ln.\--- d M E W: fi l i 1 H 4 w i M q 5 4 w Mfl 0d. 14, 1969 PERSlCQ ET AL 3,472,057

BENDING PRESS Filed March 23, 1966 v 5 Sheets-Sheet :3

Oct. 14, 1969 5 ET AL 3,472,057

BENDING PRESS Filed March 23, 1966 5 Sheets-Sheet TraX/vz/sf United States Patent 3,472,057 BENDING PRESS George .I. Persico and Luther R. Steele, Racine, Wis., assignors to Walker Manufacturing Company, a corporation of Delaware Filed Mar. 23, 1966, Ser. No. 536,686 Int. Cl. B21d 13/02 US. Cl. 72396 20 Claims ABSTRACT OF THE DISCLOSURE A bending press for performing a succession of bends which may have different depths. The press embodies a control device that consists of a hub member and radially extending control rods that coact with a stop mechanism for controlling the depth of the bends.

This invention relates to a bending press and to a control device for a bending press.

Bending presses are used for a wide variety of purposes and may, on production line basis, perform a series of successive operations that require the same or different degrees of movement. Although various control devices have been provided for accomplishing the predetermined sequence of movements, these devices have not been fully satisfactory for all operations. It is, therefore, a principal object of this invention to provide an improved control device for a bending press.

It is another object of this invention toprovide a bending press control device that permits a succession of bends to be made of selective depths.

A bending press embodying this invention includes a control device comprised of a hub member that supports a plurality of radially extending control rods. Adjustable stop means are carried by each of the control rods for adjusting the depth of bend made by the press. Ratchet means sequentially index the hub member and the control rods carried by it upon the completion of a bending cycle. Means are provided for returning the hub member to a home position after the formation of a predetermined number of bends.

Various types of actuating devices have been employed for operating the press ram that carries its bending die. In the most common form of bending press, the bending die is actuated by a hydraulic cylinder, the piston rod of which is directly coupled to the ram that carries the bending dies. This type of construction limits the press capacity and the cylinder location obstructs access to the press.

It is, therefore, another object of this invention to provide an improved actuating mechanism for a bending press.

It is a yet further object of this invention to provide a press actuating mechanism that permits free access to the bending dies of the press.

It is another object of the invention to provide a mechanism for actuating a bending press ram that magnifies the force of the actuating element.

A bending press embodying the aforenoted features is comprised of a base upon which a pair of Wing dies are supported for pivotal movement about parallel axes. The bending die is supported for reciprocal movement in a plane perpendicular to the plane defined by the wing dies axes for coaction with the wing dies. The bending die is actuated by means of a power device having two relatively movable elements. One of the power device elements is pivotally connected to the base and the other element is pivotally connected to an actuating arm. The actuating arm is pivotally supported by the base intermediate its ends and is pivotally connected at its other end to the bending die.

ice

Other objects and advantages of this invention will become more apparent as this description proceeds, particularly when considered in conjunction with the accompanying drawings, wherein:

FIGURE 1 is a side elevationl view, with portions broken away, of a bending press embodying this invention;

FIGURE 2 is a top plan view of the press shown in FIGURE 1 with portions broken away;

FIGURE 3 is a front elevational view of the press;

FIGURE 4 is an enlarged cross-sectional view taken generally along the line 4--4 of FIGURE 2;

FIGURE 5 is an enlarged rear elevational view, with portions broken away; and

FIGURE 6 is a schematic illustration of the hydraulic circuit of the press.

Referring now in detail to the drawings and in particular to FIGURES 1 through 5, a bending press embodying this invention is identified generally by the reference numeral 11. The bending press 11 is particularly adapted to bend pipe to form components of an automotive exhaust system. It is to be understood, however, that this invention may be practiced with other types of presses than pipe bending presses. The press 11 includes a base assembly, indicated generally by the reference numeral 12 and having an upstanding portion 13 on which vertically extending ways 14 are formed. An upper slide 15 is slidably supported upon the ways 14 at the forward end of the press 11. The upper slide 15 is affixed to an outwardly extending upper gooseneck 16 that carries a pair of

bending dies

17 and 18. The bending dies 17 and 18 are of different radius for a reason which will become more apparent as this description proceeds. It is to be understood that a single bending die could be carried by the upper gooseneck 16, but the use of two bending dies gives more versatility to the press 11.

A lower slide 19 is carried upon the ways 14 below the slide 15. The lower slide 19 carries a lower gooseneck 21 that functions as a support for wing die assemblies 22 and 23 that cooperate with the bending dies 17 and 18, respectively. The wing die assembly 22 comprises a pair of wing dies 24 and 25 supported in wing die nests 26 and 27 that are pivotally supported upon the lower gooseneck 21 in a known manner. In a like manner, the wing die assembly 23 is comprised of a pair of wing dies 31 and 32 supported in wing die nests 33 and 34, respectively, which are also pivotally supported upon the lower gooseneck 21.

The upper gooseneck 16 and bending

dies

17 and 18 are actuated by means of a power device, indicated generally by the reference numeral 36 and an operating linkage including an arm assembly, indicated generally by the reference numeral 37. The power device 36 is in the form of a hydraulic cylinder having a pair of relatively movable elements comprising a cylinder assembly 38 and a piston 39 (FIGURE 6) that operates through a piston rod 41. The upper end of the piston rod 41 is connected to a forked clevis 42 that receives one end 43 of the arm assembly 37. The arm end 43 is pivotally connected to the clevis 42 by means of a pivot pin 44. The forward end of the arm assembly 43 is fixed in any suitable manner to a pair of spaced arms 46 and 47 that span an upstanding trunnion 48 formed on the press base 12. The arms 46 and 47 are pivotally supported upon the trunnion 48 by means of a pivot pin 49. The forward ends of the arms 46 and 47 are afiixed to a common operating arm end 51 that carries a pivot pin 52 at its forward extremity. The pivot pin 52 pivotally connects the arm end 51 with a pair of spaced

toggle links

53 and 54 which are in turn pivotally connected at their lower end to the upper gooseneck 16 of a pivot pin 55.

The lower end of the cylinder assembly 38 is formed with a trunnion 56 that is pivotally supported upon the base 12 by means of a pivot pin 57. Thus, actuation of the power device 36 causes the piston rod 41 to be extended and pivot the arm assembly 37 about the pivot pin 49 and drive the uppor gooseneck 16 downwardly. The pivotal connection between the cylinder, trunnion 56 and base 12, will permit limited angular movement of the power device 36 during this operation.

The vertical position of the lower gooseneck 21 is controlled by a hydraulic cylinder assembly, indicated generally by the reference numeral 58. The cylinder assembly 58 includes a cylinder 59 that is suitably fixed relative to the base 12. A piston 60 (FIGURE 6) of the cylinder assembly 58 is connected to a piston rod 61 that carries a yoke 62 at its upper end. The yoke 62 receives a depending boss 63 formed integrally with the lower gooseneck 21 and is pivotally connected to the boss 63 by means of a pivot pin 64.

Contained within a control panel, indicated generally by the reference numeral 65 (FIGURE 1) at one side of the machine is a control device 66 for limiting the successive depth of bends made by the press 11. The control device 66 is comprised of a hub portion 67 from which a plurality of limit

stop control rods

68, 69, 71, 72, 73, 74, 75, 76, 77, 78, 79 and 81 radiate. The control rods 68, 69, 71-79 and 81 are screw threaded members upon which stop nuts 82 through 89 and 91 through 94, respectively, are threaded. The stop nuts coact with a limit switch, indicated generally by the reference numeral 95 and having a contact arm 96. The limit switch 95 is carried by a diagonal strut 9, one end of which is afiixed to the lower gooseneck 21 in any suitable manner.

A limit switch 101 having a contact arm 102 is supported at the top of the control panel 65 adjacent the outer end of the control rods. The limit switch contact arm 102 is adapted to be contacted by a reset screw 103 that is threaded into the outer end of the control rod 68. The limit switch 101 coacts to return the control device 66 to a reset or home position, as will become more apparent as this description proceeds.

The hub member 67 of the control device 66 is affixed to a shaft 104 that extends across the press 11 and has a ratchet wheel 105 affixed to its opposite end (FIGURE 4). A pawl 106 carries a detent 107 at its lower end that is adapted to coact with the ratchet wheel 105 to selectively index the shaft 104 and control device 66 at the completion of each bending operation. The pawl 106 is pivotally connected, by means of a pivot pin 108 at its upper end to a pusher shaft 109 that is supported by a guide 111 formed in the base 12. At the upper end of the pusher shaft 109 a smaller screw threaded portion 112 is formed and defines a shoulder 113. A spring retainer 114 is formed on the base 12 and has a forked end that extends toward the threaded end 112 adjacent the shoulder 113. A coil spring 115 bears against the spring retainer 114 and a nut 116 that is threaded onto the upper end of the pusher shaft 109. A stop member 117 is threaded into a collar 118 that is affixed to an arm attachment 119 carried by the arm assembly 37. Contact between the stop member 117 and the pusher shaft portion 109 functions to sequentially index the ratchet wheel 105, as will become more apparent as this description proceeds.

Bounce-back of the ratchet wheel 105 is precluded by means of a stop lever 121 that carries a stop pin 122 at its outer extremity. The lever 121 is pivotally supported at its opposite end by means of a pivot pin 123 that is afiixed in any suitable manner to the base 12. The lever 121 is normally biased in a clockwise direction by means of a spring (not shown) so that the pin 122 will be received in the recesses of the ratchet wheel 105 to preclude reverse rotation.

A pinion gear 126 is aifixed to the shaft 104 adjacent the ratchet wheel 105. The pinion gear 126 meshes with a vertically extending rack 127 which cooperates with an actuating arm 128 in a manner that will become apparent as this description proceeds. The arm 128 is operatively coupled to a piston rod 129 of a piston 130 of a hydraulic cylinder assembly 131. The cylinder assembly 131 is affixed in any suitable manner to the base 12. An idler gear 132 is supported upon a stub shaft 133 and engages the rack 127 below the pinion 126 to guide its movement. The lower end of the arm 128 is adapted to engage a contact arm 134 of a limit switch 135. The rack 127 and pinion 126 serve to rotate the control device 66 back to its home position, in a manner which will become more apparent as this description proceeds.

A camming lever 137 is journaled upon the shaft 104 and has a pair of apexes 138 and 139 which are adapted to engage the pawl 106 and the lever 121, respectively. The other apex 141 of the camming lever 137 is pivotally connected, by means of a pivot pin 142, to a piston rod 1430f a hydraulic cylinder assembly 144. The lower end ofthe cylinder assembly 144 is formed with a boss 145 that is pivoted to a bracket 146 by means of a pivot pin 147. The bracket 146 is fixed to the press base 12.

The upper end of the arm 128 carries a projection (not shown) that is adapted to engage a contact arm 148 of a limit switch 149 to limit the stroke of the arm 128 in one direction. A further limit switch 151 is afi'ixed to the base 12 adjacent the arm assembly 37 and has a contact arm 152 that is adapted to be engaged by the arm assembly 37.

Operation The drawings illustrate the press 11 as it appears at the end of a full bending cycle and after the control rod 68 has been positioned so that the limit stop screw 103 contacts the contact arm 102 of the limit switch 101 to initiate the return of the control device 66 to its home posi ion. The recycling operation will be described below. It is assumed for the present time that the control device 66 has been reset at its home position and the machine 11 is ready to perform the next bend.

To initiate a bending operation, the operator places a pipe onto the appropriate pair of wing dies 22 or 23, depending upon the radius bend which is to be formed. An operating switch (not shown) is then closed to initiate a cycle operation. Initiating the cycle of operating causes a solenoid valve, indicated generally by the reference numeral 161 (FIGURE 6) to be actuated causing its slide 162 to move to the right as seen in this figure. This movement of the solenoid valve slide 162 connects a conduit 163, that is fed with hydraulic fluid under pressure from a pump 164 or other sutiable source to a conduit 165 that extends to the hydraulic cylinder assembly 37 on the lower side of the piston 39 to urge the piston rod 41 ouwardly and rotate the arm assembly 37 in a clockwise direction about the pivot pin 49. The hydraulic fluid that is driven from the cylinder 38 is returned to a sump 166 by means of a conduit 167 and conduit 168. The conduit 168 is connected to the sump 166 through a solenoid valve 171 and return line 172.

The arm assembly 37 rotates in a clockwise direction causing the toggle links 53 and 54 to exert a downward pressure upon the upper gooseneck 16 until the appropriate bending die 17 or 18 contacts the pipe. When the arm assembly 37 begins this movement, the stop nut 117 (FIGURE 4) will move away from the respective end of the pusher shaft 109. The coil spring 115 then urges the pusher shaft upwardly drawing the pawl 106 with it. The pawl detent 107 then rides over the lobes of the ratchet wheel 105 until it registers with its next recess. The detent 107 is urged into this recess by means of a spring (not shown). Contact of the shoulder 113 with the spring retainer 114 limits the upward movement. The stop nut 117 will move away from the pusher shaft end 112 on further movement.

When the pipe is contacted by the bending die, the downward force exerted upon it will cause a downward reaction on the lower gooseneck 21 causing the lower slide 19 to move downwardly and follow the operation of the upper gooseneck 16. The downward movement of the lower gooseneck 21 is permitted by fluid leakage past the piston 60 of the cylinder assembly 58. This movement is transmitted through the bracket 97 to the limit switch 95 until its contact arm 96 contacts the respective stop nut 82 on the control rod presented to it by the control device 65.

When the switch 95 is closed, the solenoid valve 161 is actuated to cause its slide 162 to move to the left and the solenoid valve 171 is actuated causing its slide 173 to move to the right, both as viewed in FIGURE 6. When the

valves

161 and 171 are in these positions, the pump 164 supplies fluid under pressure through the conduit 167 to the hydraulic cylinder 36 causing the piston 39 to be retracted and draw the control piston rod 41 downwardly. The hydraulic fluid is driven from the cylinder 38 and is discharged through the

conduits

165 and 168 and valve slide 173 into a conduit 175. The piston 60 is then urged upwardly along with its piston rod 61 to return the lower gooseneck 22 to its normal, at rest position. Fluid is discharged from the opposite side of the cylinder 59 to the sump 166 via a conduit 176 and the solenoid valve slide 173.

The counterclockwise rotation of the arm assembly 37 upon its return stroke brings the stop nut 117 into engagement with the end of the pusher shaft 109. The shaft 109 and pawl 106 are then urged downwardly compressing the coil spring 115 and rotating the ratchet wheel 105. The stop pin 122 of the stop lever merely rides over the ratchet wheel during this movement. Rotation of the ratchet wheel 105 turns the shaft 104 to bring the next successive control rod of the control device 66 into a vertical position since the angular spacing of the control rods is equal to that of the ratchet wheel recesses.

When the ratchet wheel 105 and shaft 104 are indexed, the pinion 126 incrementally raises the rack 127. When the arm assembly 37 is returned to its normal at rest position, the contact arm 152 of the switch 151 is engaged and the

solenoid valves

161 and 171 are returned to the neutral position shown in FIGURE 6.

As has previously been noted, each operation of the arm assembly 37 and lower gooseneck assembly 21 causes the control device 66 to be indexed. This brings a new depth of bend control into operation. When the control device is moved to its last position, the stop nut 103 contacts the arm 102 of the limit switch 101. When this occurs, a solenoid valve indicated generally by the reference numeral 181 is actuated so that its slide 182 moves to the right. Hydraulic fluid under pressure then flows from the pump 164 through a conduit 183 and valve slide 182 to a conduit 184 that extends to the lower side of the piston of the cylinder assembly 144. This causes its piston rod 143 to be urged upwardly rotating the camming lever 137 in a clockwise direction as viewed in FIGURES 6 and 4. The clockwise rotation of the camming lever 137 causes the ratchet pawl 107 and locking pin 121 to be rotated free of the ratchet wheel 105. At the same time, hydraulic fluid is delivered through a line 186 to the cylinder assembly 131 causing its piston rod 129 to move upwardly as viewed in FIGURE 6 and downwardly as viewed in FIGURE 4.

The movement of the piston rod 129 is transmitted to the rack 127 through a pin 187 that is received in a slot 188 formed in the rack 127. At the beginning of this movement, the previous movement of the rack 127 caused by rotation of the shaft 104 and pinion 126 will have caused the slot 188 to be traversed by the pin 189 and it will be in direct engagement with the rack 127. As the piston 130 moves through the stroke, the rack 127 will be moved and shaft 104, which is now free to rotate, will be turned. The control device 66 will thereby be returned to its home position. The fluid driven from the

cylinders

144 and 131 is returned to the sump 166 through conduits 191 and 192, respectively, as well as through valve slide 182 and a return conduit 193. The aforedescribed movement of the piston rod 129 and rack 127 occurs until the contact arm 134 of the switch 135 is engaged. When this occurs, the solenoid valve 181 is actuated so that its slide 182 moves to the left through the neutral position. This movement will have occurred at the point when the control device 66 is returned to its home position. When the valve slide 182 is moved all the way to the left, hydraulic fluid will flow under pressure from the line 183 to the line 191 above the piston of the assembly 144. This causes the locking cam 137 to be rotated back to its engaged position as shown in the drawings. In addition, hydraulic fluid flows under pressure through the line 192 to the piston assembly 131 causing the piston and its piston rod 129 to be moved upwardly as viewed in FIGURE 4 and downwardly as viewed in FIGURE 6. When this happens, the pin 187 will traverse the slot 188 so that the rack 127 is retained in its home position. When the piston rod 129 is fully retracted, switch 149 will be closed causing the valve slide 182. to be returned to its neutral position. The press 11 is now ready for another complete cycle.

The hydraulic circuit and mechanism for the press has been described only generally. It is to be understood that the exact hydraulic construction is believed to be within the scope of one skilled in the art. That is, given the general disclosure contained herein, one skilled in the art could readily select the appropriate prior art components to achieve the stated function. In a like manner, the electric circuit has not been described other than by means of the sequence in which the various devices are operated. The location and operation of the necessary electrical switches has been described and the design of the circuit or circuits required to perform the stated function are within the scope of those skilled in the art.

It should be readily apparent that the described press lends itself to the performance of a predetermined sequence of bends. The successive bends may be of the same depth or different depths as determined by adjusting the control device 68. In addition, various radius bends may be made on any sequence since both bending dies 17 and 18 are carried by a common gooseneck.

While it will be apparent that the preferred embodiments of the invention disclosed are well calculated to fulfill the objects above stated, it will be appreciated that the invention is susceptible to modification, variation and change without departing from the proper scope or fair meaning of the sub-joined claims.

What is claimed is;

1. A control mechanism for controlling the successive depths of bends made by a bending press comprising a hub member, a plurality of control rods extending radially outwardly from said hub member, adjustable stop means carried by each of said control rods for adjusting the depth of bend, ratchet means for sequentially indexing said hub member upon the completion of a bending cycle, and means for returning said hub member to a home position after the formation of a predetermined number of bends.

2. A bending press control device as set forth in claim 1 wherein the ratchet means comprises a ratchet wheel, pawl means for sequentially indexing said ratchet wheel and locking means for precluding reverse rotation of said ratchet wheel.

3. A bending press control device as set forth in claim 1 wherein the means for returning the hub member to its home position comprises a stop device carried by one of the control rods, a hydraulic motor actuated by said stop device and a rack and pinion for transmitting motion from said hydraulic motor to said hub member.

4. A bending press control device as set forth in claim 2 wherein the means for returning the hub member to its home position includes means for releasing the ratchet wheel locking device and for moving the pawl out of engagement with the ratchet wheel.

5. A bending press control device as set forth in claim 4 wherein the means for releasing the ratchet wheel locking device and for moving the pawlout of engagement with the ratchet wheel comprises a pivotally supported triangular cam member and a hydraulic motor for pivotally moving said cam member.

6. A bending press control device as set forth in claim 5 wherein the means for returning the hub member to its home position comprises a stop device carried by one of the control rods, a second hydraulic motor actuated by said stop device, and a rack and pinion for transmitting motion from said second hydraulic motor to said hub member.

7. A bending press having a base, a pair of wing dies supported upon said base for pivotal movement about parallel axes, a bending die supported for reciprocal movement in a plane perpendicular to the plane defined by said axes for coaction with said wing dies, a hydraulic actuator having two relatively movable elements, means pivotally connecting one of said elements to said base, an actuating arm pivotally supported by said base, means pivotally connecting the other of said hydraulic actuator elements to one end of said actuating arm, and means pivotally connecting the other end of said actuating arm to said bending die for movement of said bending die in its plane upon relative movement between said power device elements.

8. A bending press as set forth in claim 7 wherein the means pivotally connecting the other end of the actuating arm to the bending die comprises at least one link pivotally connected at one of its ends to said arm end and having an operative pivotal connection at its other end to said bending die.

9. A bending press as set forth in claim 8 wherein two bending dies of different radius are supported for simultaneous movement, the other link end having its operative pivotal connection to both of said bending dies, and two sets of wing dies for cooperation with the respective bending die.

10. A bending press as set forth in claim 8 wherein the hydraulic actuator has a cylinder element and a piston element, the cylinder element being pivotally connected to the base and the piston element being pivotally connected to the actuating arm.

11. A bending press as set forth in claim 7 wherein the wing dies are supported for pivotal movement upon a lower ram, and further including a power device having relatively movable elements, one of said power device elements being supported by said base and the other of said elements being connected to said lower ram.

12. A bending press as set forth in claim 11 including control means for sequentially actuating the hydraulic actuator for actuating the binding die and permitting the power device to retract until said bending die has travelled a predetermined degree of movement, and for returning said bending die and said power device at the completion of the movement.

13. A bending press as set forth in claim 12 wherein the control means is effective to perform a sequence of movements of the bending die, the movement in each sequence being selectively adjustable for altering the depth of bend.

14. A bending press as set forth in claim 10 wherein the hydraulic unit is supported at the rear of the base and the bending die is supported at the front of the base, the actuating arm extending substantially from the rear of the base to the front of the base for providing free access to the wing dies.

15. A bending press as set forth in claim 13 wherein the control means comprises a hub member, a plurality of control rods radiating from said hub member, adjustable stop means carried by each of said control rods for adusting the depth of bend, ratchet means for sequentially indexing said hub member upon the completion of a bending cycle, and means for returning said hub member to a home position after the formation of a predetermined number of bends.

16. A bending press as set forth in claim 15 wherein the ratchet means comprises a ratchet wheel fixed for rotation with the hub member, pawl means for sequentially indexing said ratchet wheel, means for interconnecting the actuating arm with said pawl means for actuating said pawl means upon operation of said actuating arm, and locking means for precluding reverse rotation of said ratchet wheel.

17. A bending press as set forth in claim 15 wherein the control means is effective to perform a sequence of movements of the bending die, the movement in each sequence being selectively adjustable for altering the depth of bend.

18. A bending press as set forth in claim 16 wherein the means for returning the hub member to its home position includes means for releasing the ratchet wheel locking device and for moving the pawl out of engagement with the ratchet wheel.

19. A bending press as set forth in claim 18 wherein the means for releasing the ratchet wheel locking device and for moving the pawl out of engagement with the ratchet wheel comprises a pivotally supported triangular cam member and a hydraulic motor for pivotally moving said cam member.

20. A bending press as set forth in claim 19 wherein the means for returning the hub member to its home position comprises a stop device carried by one of the control rods, a second hydraulic motor actuated by said stop device, and a rack and pinion for transmitting motion from said second hydraulic motor to said hub memher. 1 References Cited UNITED STATES PATENTS Re. 5,381 4/1873 Palmer 72456 1,948,474 2/1934 Meyer 7239 6 2,456,675 12/1948 Chaille 72--396 2,887,141 5/1959 Bower 72-396 3,126,045 3/1964 Streit 72-421 RONALD D. GREFE, Primary Examiner US. Cl. X.R. 72-441, 450, 456