JP3639201B2 - Press brake - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a press brake suitable for pressing a workpiece pressed between a male die and a workpiece and pressing the workpiece between them, particularly for bending a long workpiece.
[0002]
[Prior art]
The press brake is a device suitable for press-bending a long plate material, for example, by pressing a punch as a male die held by a slide table against a die as a female die supported by a fixed table. It is an apparatus that press-bends a workpiece sandwiched between them into a desired shape by meshing. A fixed table is located under the slide table, and the slide table descends and press-bend processing is used for the top drive system. The fixed table is positioned above the slide table and the slide table rises and press-bend. The format is called the underslide method.
[0003]
The bending accuracy of this press brake is determined mainly by the meshing accuracy of the punch and die, that is, whether or not the same meshing occurs at any position of the workpiece. Other factors include the plate thickness accuracy of the workpiece. , Internal stress of the workpiece, and punch and die processing accuracy. Good workpiece thickness accuracy, no internal stress remains, and good punch and die machining accuracy must be satisfied before the press brake bending operation. The die engagement accuracy is a factor that is required to be maintained well during the press brake bending operation.
[0004]
Factors that affect the accuracy of the punch-die engagement include distortion of the frame that supports the fixed table and slide table (so-called mouth opening), deflection of the fixed table or slide table itself, and stroke length in the width direction of the slide table. Variation.
[0005]
As a technique for improving the bending accuracy of such a press brake, for example, as described in Japanese Patent Application Laid-Open No. 08-300047, a back plate of a ram (slide table) is provided with a side plate and a belt-like beam. A correction bracket is provided, the side plate is fixed to the left and right rear surfaces of the lower table (fixed table), a linear encoder is attached to the beam, and the ram motion is transmitted to the linear encoder via a rod with one end connected to the ram. Is detected with reference to the lower table, and a drive mechanism is operated and corrected in accordance with the detection result of the ram position.
[0006]
[Problems to be solved by the invention]
In the press brake disclosed in the above publication, the position of the ram is detected with reference to the left and right positions of the lower table. The reference ram deflection and frame distortion can be accurately detected, but other deflections cannot be accurately detected. In particular, there is a problem that the position of the ram cannot be directly detected with reference to the left and right central portions of the lower table with relatively large deflection.
[0007]
For this reason, in this press brake, a complicated process is required in which the load displacement of the lower table is calculated as a correction value by a bending load and is corrected based on this calculation value. And since this correction does not directly detect the load displacement of the lower table, the structure of the control device becomes complicated.
[0008]
Therefore, the object of the present invention is to solve the above-mentioned problems, directly detect the relative positions of the slide table and the fixed table in the vicinity of each drive mechanism, and correct and control the drive mechanism of the slide table to fix the bending table during the bending operation. An object of the present invention is to provide a press brake capable of maintaining good meshing accuracy between a mold and a movable mold.
[0009]
[Means for Solving the Problems]
  The present invention has been proposed in order to achieve the above object, and according to a first aspect of the present invention, there is provided a fixed table fixed to the front surface of a frame, and the fixed table attached to the front surface of the frame so as to be movable up and down. A horizontally long fixed mold mounted on the fixed table and a slide table mounted on the slide table. In a press brake that presses a workpiece by pressing the workpiece between a horizontally long movable mold,
  A plurality of input units respectively connected to the slide table in the vicinity of the mounting position of the drive mechanism;
  A plurality of output units arranged corresponding to the input unit on the fixed table side located below the input unit;
  A slide table vertical movement transmission mechanism that inputs the vertical movement of each input unit as a mechanical displacement amount and separately transmits the vertical movement of the output unit corresponding to each input unit;
  A plurality of detection means provided for each output unit in a state of being fixed to the fixed table side, and electrically detecting a relative position change with the output unit;
  A control device for controlling the operation of the drive mechanism based on the respective position change signals sent from the detection means;
With
  The slide table vertical motion transmission mechanism is
A starting lever member connected to the slide table as an input portion and extending rearward;
One end is connected to the rear end of the starting lever member, and a lifting member disposed so as to be vertically movable,
The rear end is connected to the other end of the elevating member and the end lever member is arranged in parallel to the start lever member.
The middle of the start lever member and the end lever member is supported by a support portion fixed to the frame side so as to be able to move back and forth, and is constituted by a link mechanism having the front end of the end lever member as an output portion,
  AboveThe press brake is characterized in that the control device selects and drives the drive mechanism so that the relative position changes detected by the detection means are aligned.
[0010]
  What is claimed in claim 2The drive mechanism is constituted by a jack mechanism including at least a ball nut, a ball screw screwed into the ball nut, and a servo motor that rotates either the ball nut or the ball screw;
2. The press brake according to claim 1, wherein at least two drive mechanisms are provided, and a slide table vertical movement transmission mechanism and a detection unit are provided in a one-to-one correspondence with each drive mechanism.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. Here, Fig.1 (a) is a front view which shows the press brake of 1st Embodiment, (b) is the side view. FIG. 2 is a top view showing the press brake of the first embodiment. FIG. 3 is a schematic diagram illustrating a drive mechanism in the press brake according to the first embodiment. FIG. 4 is a schematic view showing a fixed mold and a movable mold in the press brake of the first embodiment. Fig.5 (a) is a front view which shows the linear encoder in 1st Embodiment, (b) is the top view.
[0014]
The press brake 1 according to the present embodiment is configured so that the movable mold 5 held by the slide table 4 is engaged with the fixed mold 3 supported by the upper end portion of the fixed table 2 by applying a pressing force to both the molds 3 and 5. It is an apparatus which press-bends the to-be-processed board | plate material 6 (refer FIG. 4) pinched between. The illustrated press brake 1 is a top drive type press in which the fixed table 2 is positioned below the slide table 4, and the slide table 4 is lowered by driving the drive mechanism 7 to press and bend the workpiece 6. It is configured as a brake.
[0015]
The slide table 4 and the fixed table 2 are thick flat plate-like members, and stand upright with their longitudinal directions horizontal, and are arranged with the lower end portion of the slide table 4 and the upper end portion of the fixed table 2 facing each other vertically. The slide table 4 and the fixed table 2 are arranged on the front side of the C-type frame 8 and are directly or indirectly supported by the C-type frame 8. This C-type frame 8 is a rigid body in which a C-type side frame 8a is erected on the left and right sides, the lower ends of both side frames 8a are joined together by a lower lateral frame 8b, and the upper end parts are joined together by an upper lateral frame 8c. The fixed table 2 is fixed to the lower front surface of the side frame 8a, the drive mechanism 7 is attached to the left and right and the center of the upper horizontal frame 8c, the upper part of the slide table 4 is attached to the lower end of these drive mechanisms 7, and the slide guide (Not shown) supports the slide table 4 in a vertically movable state.
[0016]
In the present embodiment, as shown in FIG. 4, the fixed mold 3 supported by the fixed table 2 is formed as a female die having a concave portion 3 a having a V-shaped longitudinal section. On the other hand, the movable die 5 held by the slide table 4 is formed as a male punch that meshes with the female die 3, and a V-shaped concave portion of the die 3 is formed at the tip of the punch 5. A gooseneck-shaped tip pressing portion 5a having a convex shape corresponding to 3a is formed. In addition, the punch 5 is hold | maintained at the holder 4a arrange | positioned at the lower end part of the slide table 4, as shown in FIG.1 (b).
[0017]
Driving mechanisms 7 for moving the slide table 4 up and down are arranged at three equal intervals in the width direction of the slide table 4. In the present embodiment, the drive mechanism 7 is disposed at three positions in the width direction of the slide table 4, but is not limited to this, and two positions in the width direction of the slide table 4, or a plurality of four or more positions. You may arrange in. Further, it is not always necessary to arrange all the drive mechanisms at equal intervals. For example, two drive mechanisms close to each other may be arranged at equal intervals.
[0018]
As shown in FIGS. 1B and 3, each drive mechanism 7 includes a servo motor as a drive source 71, a ball nut 72 rotatably attached to the upper horizontal frame 8 c via a bearing 78, and the ball A ball screw 73 screwed into the nut 72 and having a lower end fixed to the upper end portion of the slide table 4 with a ball joint, a large diameter pulley 74 fixed to the upper end portion of the ball nut 72 with a bolt, the large diameter pulley 74 and the above-described The timing belt 76 is stretched around a small-diameter pulley 75 attached to the output shaft of the servo motor 71. The large-diameter pulley 74, the small-diameter pulley 75, and the timing belt 76 stretched over these function as a speed reducing unit 77.
[0019]
In addition, a plurality of slide table vertical movement transmission mechanisms 9 are provided on the rear surface side of the slide table 4 and the fixed table 2 so as to correspond to each drive mechanism 7 and operate independently. Since the drive mechanisms 7 are arranged at three locations in the width direction of the slide table 4, the same number of three systems of slide table vertical movement transmission mechanisms 9 are also provided.
[0020]
Each slide table vertical movement transmission mechanism 9 has a function of transmitting the movement of the slide table 4 in the vicinity of the mounting position of each drive mechanism 7 to the fixed table 2 side as a mechanical displacement amount. Input portions are respectively connected to the back surface of the slide table 4 in the vicinity of the mounting position of the drive mechanism 7, and output portions are respectively disposed on the back surface side of the fixed table 2 positioned below each input portion corresponding to the input portions, The slide table vertical movement transmission mechanism 9 inputs the vertical movement of the input unit as a mechanical displacement amount and separately transmits it as the vertical movement of the output unit corresponding to each input unit.
[0021]
The slide table vertical movement transmission mechanism 9 shown in FIGS. 1B and 2 is configured by a link mechanism formed with a plurality of intermediate fulcrums as free points that can move in the front-rear direction.
[0022]
The link mechanism includes a start lever member 93 connected to a bracket 42 provided on the back surface of the slide table 4 positioned below the drive mechanism 7 as a front end as an input portion 91 and extending backward, and a rear end of the start lever member 93. One end (upper end) is connected to the end, and an elevating member 96 arranged so as to be vertically movable, and a final movement arranged parallel to the start lever member 93 with the rear end connected to the other end of the elevating member 96. It comprises a lever member 99, and rollers 92 and 98 provided as swinging fulcrums in the middle (center) of the start lever member 93 and the end lever member 99 can be moved back and forth with the support portions 43 and 44 regulating the top and bottom. And the front end of the end lever member 99 is connected to the detection means 11 as the output unit 100. The link mechanism having such a structure is supported by fixing the lower support portion 44 side to the lower portion of the side frame 8a, and the support portion 43 side is cut off from the side frame 8a to form the side frame. It is configured not to be affected by the distortion of 8a.
[0023]
The reason why the swing fulcrum is movable back and forth is that when the slide table 4 moves linearly and the input portion 91 moves linearly, the start lever member 93 and the end lever member 99 swing smoothly and slide table. This is because the amount of movement of 4 can be accurately transmitted mechanically.
[0024]
The elevating member 96 is held by a cylindrical guide 95 provided on a cross member 102 fixed to the frame 8 side, like the support portions 43 and 44, so that it can be moved up and down. The upper end portion to be connected and the lower end portion to be connected to the rear end of the end lever member 99 are connected to each other by the rollers 94 and 97 and the support portions 45 and 46. Even if the rear ends of the moving lever members 99 move up and down in a substantially circular arc shape, the movement can be transmitted smoothly without coming off. A coil spring 101 is wound around the elevating member 96 and biased downward, thereby eliminating backlash at each connecting portion.
[0025]
The start lever member 93, the elevating member 96, and the end lever member 99 that are sequentially connected in this manner have a U-shaped side surface. Therefore, even if the workpiece is bent and the rear end rises, there is no interference. An output portion 100 at the tip of the end lever member 99 is disposed immediately below the input portion 91 at the tip of the start lever member 93. Further, a fulcrum 98 of the end lever member 99 is disposed immediately below the fulcrum 92 of the start lever member 93.
The link mechanism 9 transmits the actual movement of the slide table 4 to the detection means 11 on the fixed table 2 side, and the transmission operation will be described later.
[0026]
The detection means 11 disposed on the rear surface of the fixed table 2 is a measuring device that detects the movement of the output unit 100 transmitted from each link mechanism (slide table vertical movement transmission mechanism) 9. In this embodiment, the linear encoder (Linear scale). As shown in FIG. 5, the linear encoder 11 moves up and down along a linear guide 112 provided on the base plate 111 along the vertical direction, and the output portion 100 of the end lever member 99. Are connected to each other, a detection head 114 that measures the amount of linear change of the mobile body 113, and a signal cable 115 that transmits a detection signal. In this embodiment, as shown in FIG. 1A, the linear encoder 11 serving as the detecting means corresponds to the three drive mechanisms 7 and the three slide table vertical movement transmission mechanisms 9 to correspond to the fixed table 2. It is arrange | positioned at three places in the width direction of a rear surface.
[0027]
The amount of linear change detected by each detection means 11 is fed back to a control means (not shown) via the signal cable 115, and this control means controls the operation of each drive mechanism 7 based on the detected change amount. As the control means, for example, a microcomputer in which the contents of control are recorded is cited, and is electrically connected to the servo motor 71 of the drive mechanism 7.
[0028]
Next, a bending operation of the press brake 1 of the present embodiment and a correction operation at the time of bending will be described.
[0029]
In the initial state of the press brake 1 of the present embodiment, the slide table 4 is retracted upward, and the punch 5 and the die 3 are waiting at a predetermined interval. In this initial state, since the slide guide 4 is raised, the front end input portion 91 of the start lever member 93 is raised around the first intermediate fulcrum 92 as shown in FIG. The rear side is descending. Therefore, the elevating member 96 connected to the rear end of the start lever member 93 is also lowered. The rear end portion of the end lever member 99 connected to the lower end of the elevating member 96 is lowered, and the front end output portion 100 of the end lever member 99 is raised.
[0030]
When the servo motor 71 of the drive mechanism 7 is rotated forward during bending, the ball nut 72 is rotated forward via the small diameter pulley 75, the timing belt 76, and the large diameter pulley 74, and the slide table 4 is lowered together with the ball screw 73. Then, the punch 5 held by the holder 4a at the lower end portion of the slide table 4 is pressed toward the die 3 supported by the upper end portion of the fixed table 2, and these are engaged with each other, as shown in FIG. The workpiece 6 clamped between these is bent.
[0031]
As shown in FIG. 6 (a), bending D and d occur in the central portion in the width direction of the fixed table 2 and the slide table 4, and the fixed table 2 and the slide table 4 are When the deformation of the C-shaped frame 8 is slightly opened as shown in FIG. 6 (b) and the bending or deformation occurs, the punch 5 does not mesh with the die 3 evenly over the left and right machining ranges, and bending is performed. An error will occur in accuracy. Further, when the center of pressurization is not the center in the left-right direction but is shifted to the right side or the left side (eccentric), the deformation amount of the side frame 8a differs between the right and left. For example, in the case of so-called box bending, since the processing is performed at the left end or the right end of the table, an eccentric load acts on the frame.
In the present invention, such errors in the bending accuracy are collected on the fixed table 2 side by the slide table vertical movement transmission mechanisms 9 and detected by the detection means 11, and based on the amount of change fed back from the detection means 11. Thus, the control device controls the operation of each drive mechanism 7 to correct an error in bending accuracy.
[0032]
Specifically, when the drive mechanism 7 is driven and the slide table 4 is lowered, the input portion 91 of the start lever member 93 is lowered and swings around the intermediate fulcrum 92 in the direction in which the rear end rises. The elevating member 96 is also raised by the swinging of the start lever member 93. Then, the rear end portion of the end lever member 99 connected to the lower end portion of the elevating member 96 rises, and the end lever member 99 swings about the intermediate fulcrum 98, whereby the front end output portion 100 is input. It descends by the same length as the part 91. That is, the stroke of the slide table 4 is grasped as a linear change amount in the minus direction in the linear encoder as the detecting means 11.
[0033]
When the fixed table 2, the slide table 4 and the C-shaped frame 8 are not bent or opened, the values of the three linear encoders 11 indicate the same value. However, when the fixed table 2, the slide table 4, or the C-shaped frame 8 is bent or opened, the linear encoder 11 corresponding to the bent or opened portion shows a value inclined in the plus direction, and the linear change amount is different. Will be shown. Therefore, the difference in the amount of linear change is compared with the value of the other linear encoder 11, and the correction corresponding to the value is fed back to the drive mechanism of the linear encoder inclined in the plus direction. By correcting and controlling the operation of the mechanism 7, an error in bending accuracy is corrected.
[0034]
For example, when the stroke is set to 100 mm and it is assumed that the fixed table 2 is not bent, if the central portion of the slide table 4 is bent upward by 1 mm (d = 1.00 mm), the input portion 91 of that portion is bent. Therefore, the movement of the output unit 100 is also reduced by that amount. At this time, since the central portion of the fixed table 2 is not bent, the base plate 111 of the linear encoder 11 maintains the initial position. Therefore, even if the detection value of the left and right linear encoders 11 of the fixed table 2 is 100 mm, the detection value of the linear encoder 11 in the center portion is 99 mm, which is 1 mm less. Based on the result of this detection comparison, the control device sends out a pulse signal required to further lower the central drive mechanism 7 by 1 mm to perform a correction operation (correction of minus 1.00 mm). In this way, when the center drive mechanism 7 performs the correction operation, the center portion of the slide table 4 is driven by the amount of deflection, and the center linear encoder 11 detects a movement of 100 mm.
[0035]
Even during the correction operation, the central linear encoder 11 monitors the amount of movement of the central portion of the slide table 4, so that the numerical values of the left and right linear encoders 11 are aligned, that is, over the entire left and right. The correction operation can be repeated until uniform meshing is achieved.
[0036]
In the above processing, when the central portion of the fixed table 2 is bent 0.5 mm (D = 0.50 mm), the base plate 111 of the central linear encoder 11 is lowered 0.5 mm from the initial position. Accordingly, the detected value is detected as 98.5 mm, which is 0.5 mm smaller. Therefore, the control device sends a pulse signal necessary for lowering the central drive mechanism 7 by 1.5 mm to perform a correction operation. As a result, even if the center portion of the slide table 4 is bent by d and the center portion of the fixed table is bent by D, the engagement between the molds 3 and 5 is uniform over the entire processing range, and bending is performed with high accuracy. be able to.
[0037]
Thus, the slide table vertical movement transmission mechanism 9 provided corresponding to each drive mechanism 7 transmits the actual movement amount of the slide table 4, that is, the movable mold 5, to the detection head 114 of the linear encoder 11 on the fixed table 2 side. Then, the base plate 111 of the linear encoder 11 fixed on the fixed table 2 side is displaced according to the displacement amount of the fixed table 2, that is, the fixed mold 3, whereby each detecting means 11 detects the error on the slide table 4 side and the fixed table 2. And detection errors can be fed back to the control means, and the control means controls the operation of each drive mechanism 7 based on the comparison difference between the detection results. Accordingly, it is possible to accurately detect an error in the bending process accuracy of the top drive type press brake 1 and correct and control the drive mechanism 7 of the slide table 4, and to improve the meshing accuracy between the punch 5 and the die 3 during the bending process. It can be maintained well.
[0038]
When the bending process is completed, when the servo motor 71 of the drive mechanism 7 is reversely driven, the ball nut 72 rotates reversely, and the slide table 4 rises together with the ball screw 73. Along with this, each slide table vertical movement transmission mechanism 9 returns to the initial state.
[0039]
Next, the press brake of the second embodiment will be described. Here, FIG. 7 is a side view showing the press brake of the second embodiment. As shown in the figure, in the press brake 21 of the second embodiment, the fixed table 22 is positioned above the slide table 24, and the slide table 24 is raised by driving the drive mechanism, so that the workpiece is press-bended. It is configured as an underdrive press brake to be processed. In the present embodiment, the movable die 25 supported on the upper end portion of the slide table 24 is formed as a female die having a concave portion having a V-shaped longitudinal section. On the other hand, a fixed die 23 held at the lower end of the fixed table 22 is formed as a male punch that meshes with the female die 25, and a V-shape of the die 25 is formed at the tip of the punch 23. A pressing portion having a convex shape corresponding to the concave portion is formed. Therefore, the drive mechanism and the control device (not shown) are accommodated in the lower position of the C-shaped frame 28.
[0040]
Moreover, the linear encoder as the detection means 31 is arrange | positioned at the rear surface of the fixed table 22 located in the upper part. Further, a plurality of drive mechanisms are provided in the width direction of the lower slide table 24, and the same number of link mechanisms as the slide table vertical movement transmission mechanism 29 and the linear encoders 31 are arranged corresponding to the drive mechanisms. . Since it is an underdrive type press brake 21 and the linear encoder 31 is disposed on the rear surface of the fixed table 22 located at the upper part, the operation of the link mechanism 29 shows the reverse movement of the first embodiment. .
[0041]
As described above, the press brake 21 of the second embodiment is an underdrive type press brake capable of maintaining good meshing accuracy between the fixed die (punch) 23 and the movable die (die) 25 during the bending operation. Basically, the same operational effects as those of the first embodiment are achieved.
[0049]
In addition, this invention is not limited to above-described embodiment, Based on description of a claim, a various deformation | transformation is possible. For example, a gear type reduction mechanism may be provided as a reduction means for the drive mechanism. In the embodiment, the drive mechanism rotates the ball nut 72 without rotating the ball screw 73. However, the ball nut 72 may be fixed to the slide table side by rotating the ball screw 73. Further, the drive mechanism 7 for driving the slide table 4 is not limited to the ball screw type, and may be constituted by a hydraulic jack.
[0050]
【The invention's effect】
As described above, the present invention has the following effects.
That is, according to the first aspect of the present invention, the slide table vertical movement transmission mechanism provided corresponding to each drive mechanism transmits the movement of the slide table in the vicinity of the drive mechanism mounting portion to the fixed table side, and each transmission The amount of movement transmitted from the mechanism is detected by each detection means based on the corresponding portion of the fixed table and fed back to the control means, so that the control means operates each drive mechanism based on the amount of change. To control. Therefore, it is possible to accurately detect the error in the bending accuracy of the press brake as a linear change amount, and to correct and control the drive mechanism of the slide table, and maintain good engagement accuracy between the fixed mold and the movable mold during the bending operation. can do.
[0051]
  AndSince the slide table vertical motion transmission mechanism is configured by a link mechanism, and the middle of the start lever member and the end lever member are supported by the support portions fixed to the frame side so that they can move back and forth, the slide table moves linearly. Thus, even if the tip of the starting lever member, which is the input portion, linearly moves, the support portion serving as the swing fulcrum moves the starting lever member back and forth and swings smoothly. The end lever member swings smoothly in the same manner. Therefore, the linear movement of the slide table can be output smoothly, and each detection means can detect with high accuracy, and high accuracy correction can be expected.
[0053]
  Claim2According to the invention described in (1), the drive mechanism is composed of a jack mechanism including a ball nut and a ball screw screwed to the ball nut. At least two drive mechanisms are provided, and each drive mechanism has a one-to-one correspondence. Correspondingly, since the slide table vertical movement transmission mechanism and the detection means are provided, the movement amount of the slide table can be directly and accurately detected based not only on the right and left of the fixed table but also on the middle of the left and right. Accordingly, appropriate correction can be made between the left and right sides of the fixed table without depending on the calculation, particularly in the central portion where distortion is likely to occur and accuracy is difficult to obtain.
[Brief description of the drawings]
FIG. 1A is a front view showing a press brake according to a first embodiment, and FIG. 1B is a side view thereof.
FIG. 2 is a top view showing the press brake of the first embodiment.
FIG. 3 is a schematic view showing a drive mechanism in the press brake of the first embodiment.
FIG. 4 is a schematic view showing a fixed mold and a movable mold in the press brake of the first embodiment.
FIG. 5A is a front view showing the linear encoder in the first embodiment, and FIG. 5B is a top view thereof.
FIG. 6A is a view showing a bending state of a fixed table and a slide table, and FIG. 6B is a side view showing an opening state of a side frame.
FIG. 7 is a side view showing a press brake of a second embodiment.
[Explanation of symbols]
    1 Press brake
    2 fixed table
    3 Fixed type
      3a V-shaped recess
    4 Slide table
      4a Holder
    5 Mobile type
      5a Corner
    6 Work material
    7 Drive mechanism
    8 C-type frame
      8a Side frame
      8b Lower horizontal frame
      8c Upper horizontal frame
    9 Slide table vertical motion transmission mechanism
  11 Detection means (linear encoder)
  21 Press brake
  22 fixed table
  24 Slide table
  23 Fixed type
  25 Mobile type
  28 C-type frame
  29 Slide table vertical motion transmission mechanism
  31 Detection means
  41 Press brake
71 Drive source (servo motor)
  72 Ball nut
  73 Ball screw
  74 Large diameter pulley
  75 Small diameter pulley
  76 Timing belt
  77 Deceleration means
  78 Bearing
  91 Input section
  92 Roller as intermediate fulcrum
  93 Start lever member
  94 Roller as an intermediate fulcrum
  95 Guide
  96 Lifting member
  97 Roller as an intermediate fulcrum
  98 Roller as an intermediate fulcrum
  99 End lever member
100 output section
101 Coil spring
102 Slab
111 Base plate
112 Linear guide
113 Mobile
114 Detection head
115 signal cable

Claims (2)

A fixed table fixed to the front surface of the frame, a slide table mounted on the front surface of the frame so as to be movable up and down and disposed at a position facing the fixed table, and a plurality of slide tables disposed in the left and right direction of the frame. A drive mechanism that moves up and down, and presses the workpiece by pressing the workpiece between a horizontally long fixed die attached to the fixed table and a horizontally long movable die attached to the slide table. In press brake,
A plurality of input units respectively connected to the slide table in the vicinity of the mounting position of the drive mechanism;
A plurality of output units arranged corresponding to the input unit on the fixed table side located below the input unit;
A slide table vertical movement transmission mechanism that inputs the vertical movement of each input unit as a mechanical displacement amount and separately transmits the vertical movement of the output unit corresponding to each input unit;
A plurality of detection means provided for each output unit in a state of being fixed to the fixed table side, and electrically detecting a relative position change with the output unit;
A control device for controlling the operation of the drive mechanism based on the respective position change signals sent from the detection means;
With
The slide table vertical motion transmission mechanism is
A starting lever member connected to the slide table as an input portion and extending rearward;
One end is connected to the rear end of the starting lever member, and a lifting member disposed so as to be vertically movable,
The rear end is connected to the other end of the elevating member and the end lever member is arranged in parallel to the start lever member.
The middle of the start lever member and the end lever member is supported by a support portion fixed to the frame side so as to be able to move back and forth, and is constituted by a link mechanism having the front end of the end lever member as an output portion,
The press brake is characterized in that the control device selects a drive mechanism so that the relative position changes detected by the detection means are aligned, and performs a correction operation. The drive mechanism is composed of a jack mechanism including at least a ball nut, a ball screw screwed into the ball nut, and a servo motor that rotates either the ball nut or the ball screw.
2. The press brake according to claim 1 , wherein at least two drive mechanisms are provided, and a slide table vertical motion transmission mechanism and detection means are provided in a one-to-one correspondence with each drive mechanism .

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