JP2021010928A - Pressurization type strain removing device - Google Patents

Abstract

To provide a pressurization type strain removing device allowing for improving efficiency of work for removing strain, thereby allowing for efficient removal of strain occurring in a workpiece.SOLUTION: A pressurization type strain removing device 1 comprises a portal shape frame 20 straddling the lateral direction LR of a surface plate 10 for placing a workpiece W thereon and movable in the longitudinal direction FB and a hydraulic cylinder 45 generating pressurization force. A main spindle head 40 is suspended from a beam portion 23 of a frame 20 slidably with respect to the beam portion 23, and the hydraulic cylinder 45 is detachably mounted to the main spindle head 40 below the beam portion 23 of the frame 20. The pressurization type strain removing device 1 further comprises an electric control unit 90 having a motor control unit 91 performing numerical control on a first servomotor 31 moving the frame 20 and a second servomotor 71 moving the main spindle head 40 and an operation unit 80 having a motor control unit 82 for operating driving to the first servomotor 31 and the second servomotor 71.SELECTED DRAWING: Figure 1

Description

The present invention relates to a pressure strain removing device that applies a pressing force to the surface of a metal plate material to deform and remove the strain generated in the metal plate material.

Products such as cans and flooring materials for transportation vehicles are formed by processing into a workpiece (workpiece) made of metal plate material by a press machine, and inevitably distortion occurs in the work piece during pressing. Will end up. Therefore, in the post-process after pressing, the strain is removed by using a strain removing device. An example of the strain removing device is disclosed in Patent Document 1.

Patent Document 1 is a document filed for patent by the present applicant, and has a portal shape that straddles the horizontal direction of the platen on which the workpiece is placed and can move in the horizontal direction and in the front-rear direction orthogonal to the vertical direction. It is a pressure type strain removing device provided with a frame and a hydraulic cylinder for generating a pressing force. In this pressure type strain removing device, the spindle head is hung on a slide portion where the beam portion of the frame can be slid, and the hydraulic cylinder is in a posture in which the rod is directed downward in the vertical direction with respect to the upper surface of the surface plate. It is detachably suspended from the support plate of the spindle head. In the strain removing work by the pressure type strain removing device, when the work having the strained portion (work with strain) is placed on the surface plate and set, the operator presses the work attached to the rod tip of the hydraulic cylinder. In order to arrange the head at a position corresponding to this strain portion, the frame is manually moved in the front-rear direction of the surface plate, and the spindle head is manually moved in the left-right direction of the beam portion of the frame.

Japanese Patent No. 5930103

However, in the pressure type strain removing device of Patent Document 1, both the movement of the frame in the front-rear direction and the movement of the spindle head in the left-right direction are manual. Therefore, every time the operator performs the strain removing work of the strained work one by one, the operator must perform the spindle head positioning work of arranging the spindle head at a position corresponding to the strained portion of the strained work. In particular, in the actual strain removing work, in the first case where strained workpieces having the same specifications are supplied to the work site in a certain number of lots, for example, several to a dozen pieces, or the strain removing work is performed. , There is only one distorted work such as a custom-made product, and there is a second case where it is continuously brought to the work site intermittently at intervals to perform distortion removal work. ..

In the first case, the strain removing work is often performed in the same manner for any strained work. In the setup work, when the distorted work is carried in or out of the surface plate on the surface plate, the position where the spindle head is temporarily retracted from the place where the distorted work is placed and the distorted part of the distorted work are set. The spindle head is moved to and from the position where the pressing head pressurizes. Such movement of the spindle head is repeated for each strained workpiece. Therefore, the burden on the operator is heavy when moving the frame and the spindle head.

Further, in the second case, the worker cannot efficiently perform the setup work each time, partly because he / she does not frequently perform the setup work for only one strained work. There was a risk. In particular, in recent years, there has been a problem in the industrial world that there is a shortage of human resources for workers and a shortage of successors to hand down the technology, so new additions have been made so that distortion removal work can be performed efficiently. The development of a pressure strain removing device has been desired.

The present invention has been made to solve the above problems, and by improving the workability related to the strain removing work, the strain generated in the work piece can be efficiently removed. The purpose is to provide a picking device.

The pressurized strain removing device according to the present invention has the following configurations in order to achieve the above object.
(1) A portal-shaped frame that straddles the left-right direction of the platen on which the workpiece is placed and can move in the front-rear direction that is perpendicular to the left-right direction and the up-down direction, and a hydraulic cylinder that generates pressing force. The spindle head is slidably suspended from the beam portion of the frame, and the hydraulic cylinder is a pressure type detachably attached to the spindle head on the lower side from the beam portion of the frame. In the strain removing device, a first servomotor that serves as a power source for the movement of the frame, a second servomotor that serves as a power source for the movement of the spindle head, the first servomotor, and the second servomotor. The control means includes a control means for controlling the servomotor, and the control means includes a motor operation unit that operates the first servomotor and the second servomotor, and the first servomotor and the second servomotor. It is characterized by having a motor control unit that numerically controls the driving of the servomotor and a storage unit that can store electrical information controlled by the motor control unit.
(2) In the pressurizing strain removing device according to (1), the frame is placed directly above one or more pressurizing portions to which a pressing force is applied by the hydraulic cylinder among the workpieces placed on the surface plate. A program for moving and arranging the spindle head and the spindle head is stored in the storage unit of the control means.
(3) The pressurized strain removing device according to (1) or (2) is characterized in that it is provided with a strain amount grasping means capable of quantitatively grasping the state of strain possessed by the workpiece. To do.

The operation and effect of the pressurized strain removing device of the present invention having the above configuration will be described.
(1) A portal-shaped frame that straddles the left-right direction of the platen on which the workpiece is placed and can move in the front-rear direction that is perpendicular to the left-right direction and the up-down direction, and a hydraulic cylinder that generates pressing force. The spindle head is slidably suspended from the beam portion of the frame, and the hydraulic cylinder is a pressure type detachably attached to the spindle head on the lower side from the beam portion of the frame. In the strain removing device, a first servomotor that is a power source for the movement of the frame, a second servomotor that is a power source for the movement of the spindle head, a first servomotor, and a second servomotor are used. The control means includes a control means for controlling, and the control means numerically controls the driving of the motor operation unit that operates the first servomotor and the second servomotor, and the first servomotor and the second servomotor. It is characterized by having a motor control unit for performing the operation and a storage unit capable of storing electrical information controlled by the motor control unit.

Due to this feature, the operator can perform the setup work for arranging the spindle head at the strained portion each time the work piece having the strained portion is subjected to the strain removing work, the frame and the spindle head. The process of arranging the above on the strained portion of the workpiece can be automatically and easily performed regardless of the quantity of the workpiece. In addition, the burden on the operator for the strain removing work can be significantly reduced as compared with the pressure type strain removing device of Patent Document 1 in which all the setup work is performed by the operator one by one. ..

Therefore, according to the pressurized strain removing device according to the present invention, by improving the workability related to the strain removing work, the strain generated in the work piece can be efficiently removed, which is an excellent effect. Play.

In the pressurized strain removing device described in (2), the frame and the spindle head are moved directly above one or more pressurized parts to which the pressing force applied by the hydraulic cylinder is applied among the workpieces placed on the surface plate. It is characterized in that the program to be arranged and arranged is stored in the storage unit of the control means.

Due to this feature, when a plurality of workpieces having strained portions have the same specifications, the setup work itself can be performed efficiently, and the time required for the setup work is, for example, a comparison with the conventional one. Since it can be significantly shortened to 1/2 or less, the productivity of the strain removing work is dramatically improved.

The pressurized strain removing device according to (3) is characterized by being provided with a strain amount grasping means capable of quantitatively grasping the state of strain possessed by the workpiece.

Due to this feature, when removing the strain of the workpiece by the pressing force of the hydraulic cylinder, the magnitude of the strain can be easily grasped by the strain amount grasping means at the position where the pressing force is applied to the strained portion of the workpiece. Therefore, it is possible to grasp the amount of strain and apply the pressing force of the hydraulic cylinder necessary for removing the strain at the strained portion reasonably and efficiently.

It is a front view which shows the pressure type strain removing apparatus which concerns on embodiment. It is a top view of the surface plate of the pressure type strain removing device shown in FIG. 1 and is an explanatory view showing a frame feed mechanism configured on the lower surface side of the surface plate. It is a side view which shows a part of the belt used for the frame feed mechanism and the spindle head feed mechanism in the pressure type strain removing device shown in FIG. Among the pressurized strain removing devices shown in FIG. 1, a side view showing a spindle head and a sliding portion thereof, and a beam portion of a portal frame are shown in a cross section taken along the line AA in FIG. It is a figure which looked at the beam part of the frame of the pressure type strain removing apparatus shown in FIG. 1 from above, and is the explanatory view which shows the spindle head feed mechanism configured on the rear side of the beam part. It is explanatory drawing which showed the pressurization part of the work placed on the surface plate of the pressurization type strain removing apparatus exemplarily. It is explanatory drawing which shows the operation unit of the pressure type strain removing apparatus. It is explanatory drawing which shows the display screen of the operation unit shown in FIG. 7.

Hereinafter, embodiments of the pressurized strain removing device according to the present invention will be described in detail with reference to the drawings. The pressurized strain removing device of the present invention presses, welds, or heat-treats a metal plate material to produce a product such as a can or a floor material of a transportation vehicle by processing the metal plate material which is the material thereof. It is used for the purpose of deforming and removing the strained portion that is inevitably generated on the surface of the workpiece (workpiece) that is in the state immediately after being processed such as by applying pressing force. ..

FIG. 1 is a front view showing a pressurized strain removing device according to an embodiment. FIG. 2 is a plan view of the surface plate of the pressure type strain removing device shown in FIG. 1 as viewed from above, and is an explanatory view showing a frame feed mechanism configured on the lower surface side of the surface plate. In the pressurized strain removing device 1 shown in FIG. 1, the left-right direction is defined as "horizontal direction LR", the vertical direction is defined as "vertical direction VT" (or vertical direction VT), and the vertical direction is defined in FIG. The direction of the pressurized strain removing device 1 is defined with the lower side as the "front side F" of the "front-rear direction FB" and the upper side as the "rear side B" of the "front-rear direction FB". And according to the direction defined in FIG. Further, in order to make the drawings easier to see, the drawings of electrical wiring, hydraulic piping, air piping, piping equipment, covers, etc. are omitted in the drawings after FIG.

As shown in FIG. 1, the pressurizing strain removing device 1 is roughly divided into a device main body 2 and an operation control unit 3, and the device main body 2 is installed on a gantry 15 in the present embodiment. .. The apparatus main body 2 has a surface plate 10, a frame 20, a spindle head 40, and the like. The operation control unit 3 is a unit in which the operation unit 80 and the electric control unit 90 (control means) are integrated, and is provided separately from the device main body 2 in the present embodiment. The surface plate 10 is made by welding a plate material having an upper surface 11 onto a surface plate frame in which ribs are crossed vertically and horizontally to increase rigidity and strength in a frame formed of a steel material (aggregate). It is configured by sticking with. A work W having a distorted portion is placed on the upper surface 11 of the surface plate 10.

The frame 20 has a portal shape that straddles the horizontal LR of the surface plate 10 and can move in the front-rear direction FB orthogonal to the horizontal direction LR and the vertical direction VT. Specifically, the frame 20 has a gate shape in which the upper portions of two pillar portions 21 parallel to each other are connected by a beam portion 23. The pillar portion 21 is formed in a substantially L shape having a receiving portion 22 on the lower side, and a rolling roller 14 is rotatably supported on the lower portion of the pillar portion 21. The rolling roller 14 travels while rolling on a guide rail 13 provided on the side portion 12 of the surface plate 10. The receiving portion 22 extends from below the side portion 12 of the surface plate 10 to the center side of the surface plate 10 so as to be engaged with the side portion 12, and is pressurized by the hydraulic cylinder 45 described later together with the guide rail 13. Occasionally, the reaction force due to the downward pressing force of the vertical VT can be received.

<Feeding mechanism of frame 20>
As shown in FIG. 2, a frame feed mechanism 30 is arranged in a space below the plate material forming the upper surface 11 of the surface plate 10 (an internal space surrounded by side portions 12 in four directions). Specifically, the frame feed mechanism 30 arranges the center of the LR in the left-right direction of the surface plate 10 along the front-rear direction FB of the surface plate 10 in the space under the plate material forming the upper surface 11 of the surface plate 10. There is. The frame feed mechanism 30 is a mechanism for freely moving the frame 20 in the front-rear direction FB of the surface plate 10 based on the drive of the first servomotor 31 (first servomotor) which is a power source. In addition to the first servomotor 31, the frame feed mechanism 30 includes two pulleys 32, a belt 33, a connecting portion 34, a driving force transmission member 35, and the like.

FIG. 3 is a side view showing a part of the belt used for the frame feed mechanism and the spindle head feed mechanism in the pressure type strain removing device shown in FIG. The first servomotor 31 is an electric motor that rotates based on numerical control, and in the present embodiment, is a stepping motor incorporating an encoder and a brake. The output shaft of the first servomotor 31 is directly driven to a pulley 32 on the drive side on the rear side B of the front-rear direction FB. The driven pulley 32 is arranged on the front side F of the front-rear direction FB under the plate material of the surface plate 10, and the belt 33 is hung on the two pulleys 32.

As shown in FIG. 3, the belt 33 is a timing belt having a plurality of teeth intermittently and having tooth tips and tooth bottoms alternately and continuously formed at intervals of a constant pitch. The pulley 32 is a timing pulley having a plurality of teeth intermittently, having intervals at a constant pitch, and having tooth tips and tooth bottoms alternately and continuously formed, and the teeth and belt of the pulley 32. The 33 teeth can mesh with each other.

As shown in FIG. 2, the connecting portion 34 is fixedly attached to a part of the belt 33. The connecting portion 34 is connected to the receiving portion 22 of the pillar portion 21 on one side of the two pillar portions 21 of the frame 20 by one driving force transmission member 35. As a result, when the first servomotor 31 is driven, its rotation is transmitted to the pulley 32 on the drive side, and as the pulley 32 interlocks with the first servomotor 31 rotates, the belt 33 becomes the two pulleys 32. Travel relatively. The connecting portion 34 can move back and forth in the front-rear direction FB within the inner range of the opposing pulleys 32, 32 by traveling the belt 33. The driving force of the first servomotor 31 is transmitted to the pillar portion 21 by the driving force transmitting member 35 linked to the traveling of the connecting portion 34.

Thus, the frame 20 can move in the front-rear direction FB with respect to the surface plate 10 while the rolling roller 14 rolls on the guide rail 13 of the surface plate 10. As shown in FIG. 2, four stoppers 36 are provided at both ends of the front-rear direction FB of the surface plate 10, and the moving range of the frame 20 is regulated by the stoppers 36 with respect to the surface plate 10. ..

By the way, in the present embodiment, the connecting portion 34 of the belt 33 is connected to the receiving portion 22 of the pillar portion 21 on one side of the frame 20 by one driving force transmitting member 35. However, in the frame feed mechanism 30, since the center of the LR in the left-right direction of the surface plate 10 is arranged along the front-rear direction FB of the surface plate 10, the rotational moment of the frame 20 hardly acts on the surface plate 10. Therefore, even if the structure is such that the rotation of the first servomotor 31 is transmitted to the belt 33 via one driving force transmission member 35, the pillar portion 21 of the frame 20 and the side portion 12 of the surface plate 10 Local contact is suppressed. Therefore, the frame 20 can smoothly move the front-rear direction FB of the surface plate 10.

Next, the spindle head 40 will be described. FIG. 4 is a view showing a side view showing a spindle head and a sliding portion thereof of the pressurized strain removing device shown in FIG. 1 and a beam portion of a portal frame in a cross section taken along the line AA in FIG. Is. FIG. 5 is a view of the beam portion of the frame of the pressure type strain removing device shown in FIG. 1 as viewed from above, and is an explanatory view showing a spindle head feed mechanism configured on the rear side of the beam portion.

<Spindle head 40 feed mechanism>
As shown in FIGS. 1 and 4, the spindle head 40 supports the hydraulic cylinder 45 and is equipped with a strain amount measuring unit 60 (strain amount grasping means). The spindle head 40 is suspended and suspended from a slide portion 41 formed in a substantially mouth shape that covers the entire circumference of the beam portion 23 of the frame 20. As shown in FIGS. 4 and 5, the slide portion 41 is held by the rolling guide 25 of the beam portion 23, and the rolling roller 42 rolls on the rolling surface 24 of the beam portion 23. As a result, the spindle head 40 can slide the beam portion 23 in the left-right direction LR.

As shown in FIGS. 4 and 5, the spindle head feed mechanism 70 is arranged in the frame 20 at a position connecting the upper portions of both pillar portions 21 along the beam portion 23. The spindle head feed mechanism 70 is a mechanism for freely moving the spindle head 40 in the left-right direction LR of the beam portion 23 based on the drive of the second servomotor 71 (second servomotor) which is a power source. is there. The spindle head feed mechanism 70 includes a second servomotor 71, two pulleys 72, a belt 73, an intermediate pulley 74, a tensioner 75, and the like.

The second servomotor 71 is an electric motor that rotates based on numerical control, and in the present embodiment, is a stepping motor incorporating an encoder and a brake. The output shaft of the second servomotor 71 is directly driven to a pulley 72 on the drive side on the left side L (left side in FIG. 5) in the left-right direction LR. The pulley 72 on the driven side is arranged on the right side R (right side in FIG. 5) in the left-right direction LR, and a belt 73 similar to the belt 33 used in the frame feed mechanism 30 is hung on the two pulleys 72. (See Fig. 3).

Further, like the pulley 32, the pulley 72 is a timing pulley which has a plurality of teeth intermittently and is formed by alternately and continuously forming a tooth tip and a tooth bottom at intervals of a constant pitch. , The teeth of the pulley 72 and the teeth of the belt 73 can mesh with each other. Tensioners 75 are provided in the vicinity of the pulley 72 on the driving side and in the vicinity of the pulley 72 on the driven side, and the tension of the belt 73 is adjusted by the adjustment by the tensioner 75.

The intermediate pulley 74 has teeth formed with the same specifications as the teeth of the pulley 72, and the teeth of the intermediate pulley 74 can mesh with the teeth of the belt 73. The intermediate pulley 74 is pivotally supported by the slide portion 41, and is a timing pulley that rotates while rotating as the belt 73 travels when meshing with the belt 73. The slide portion 41 is provided with a mechanism for converting the rotation motion of the intermediate pulley 74 into a linear motion of the beam portion 23 in the left-right direction LR.

As shown in FIG. 5, the belt 73 is hung between the two pulleys 72 together with the tensioner 75 in a state of being meshed with the intermediate pulley 74. As a result, when the second servomotor 71 is driven, its rotation is transmitted to the pulley 72 on the drive side, and the belt 73 meshes with the intermediate pulley 74 as the pulley 72 that interlocks with the second servomotor 71 rotates. However, it travels relatively between the two pulleys 72. As a result, the driving force of the second servomotor 71 is transmitted to the slide portion 41 based on the rotation motion of the intermediate pulley 74 accompanying the traveling of the belt 73. Therefore, the slide portion 41 can move back and forth in the left-right direction LR within the inner range of the pulleys 72 and 72 facing each other by the traveling of the belt 73.

Thus, the spindle head 40 can move in the left-right direction LR with respect to the beam portion 23 while the rolling roller 42 rolls on the rolling surface 24 of the beam portion 23. As shown in FIG. 5, stoppers 76 are provided on the upper portions of both pillars 21, and the movement range of the spindle head 40 is regulated by the stopper 76 with respect to the beam portion 23 of the frame 20. ..

<Function of hydraulic cylinder 45>
As described above, the spindle head 40 supports the hydraulic cylinder 45 and is equipped with the strain amount measuring unit 60 (see FIG. 1). As shown in FIGS. 1 and 4, the hydraulic cylinder 45 is arranged between the slide portion 41 of the spindle head 40 and the first support plate 47 in a posture in which the rod 46 faces downward, and is fixed to the slide portion 41. The two support plate suspension members 48 are detachably fixed and attached while holding the end surface on the rod side (lower side in FIG. 1).

Further, as shown in FIG. 4, two connecting members 51 extend vertically on the spindle head 40 so as to sandwich the beam portion 23 of the frame 20, and can slide in the cylindrical connecting member guide 52. It is inserted and held. In the two connecting members 51, the lower ends thereof are connected by the second support plate 49, and the upper ends thereof are also connected by the rod connecting member 65. A pressing head position adjusting member 53 is detachably attached to the second support plate 49, and a pressing head 54 that comes into contact with the work W is detachably attached to the lower end of the pressing head position adjusting member 53. ..

When performing the strain removing work, the rod 46 of the hydraulic cylinder 45 is extended downward, so that the propulsive force of the hydraulic cylinder 45 presses the second support plate 49 and presses it via the pressing head position adjusting member 53. It is transmitted to the head 54 as a pressing force on the work W. As a result, the strain on the work W is deformed and removed by the pressurization due to this pressing force.

<Function of strain measurement unit 60>
The strain amount measuring unit 60 is a unit capable of quantitatively measuring the state of strain held in the work W. As shown in FIGS. 1 and 4, the strain amount measuring unit 60 is arranged so as to be operable along the operating direction of the rod 46 of the hydraulic cylinder 45, and is a pressing head capable of contacting the upper surface Wa (surface) of the work W. It has a 54, a displacement detecting unit (not shown) that detects the displacement of the pressing head 54 by the amount of movement, and a display unit 66 that displays the displacement detected by the displacement detecting unit. The strain amount measuring unit 60 includes a single-acting extrusion type pneumatic cylinder that expands and contracts the rod 62 relative to the air cylinder 61 by controlling the flow of air as a fluid. The air cylinder 61 faces the sliding portion 41 of the spindle head 40 with its anti-rod side facing the slide portion 41 of the spindle head 40, and in a posture in which the rod 62 faces upward, air is placed at a position lower than the tip position of the rod 62 via the air cylinder suspension member 63. It is fixed to the cylinder fixing member 64. The air cylinder 61 communicates with and is connected to the air pressure adjusting valve 67.

In the strain amount measuring unit 60, when the rod 62 of the air cylinder 61 is shortened (in the state of being pulled downward in FIG. 4), the second support plate 49 connected to the connecting member 51 is lowered, so that the second support plate 49 Along with the descent, the pressing head 54 comes into contact with the upper surface Wa of the work W placed on the surface plate 10. At this time, the pressing head 54 plays the role of a measuring tentacle that comes into contact with the work W. While the strain amount measuring unit 60 is measuring the strain of the work W, the movement of the rod 46 of the hydraulic cylinder 45 is temporarily interrupted, and the propulsive force of the hydraulic cylinder 45 is the rod 46 of the hydraulic cylinder 45. Does not act on the second support plate 49.

<Structure of operation control unit 3>
Next, the operation control unit 3 of the pressurized strain removing device 1 will be described. FIG. 7 is an explanatory view showing an operation unit of the pressure type strain removing device, and FIG. 8 shows a display screen of the operation unit shown in FIG. 7. As shown in FIGS. 1, 7, and 8, the operation control unit 3 is a unit in which the operation unit 80 and the electric control unit 90 are integrated. The electric control unit 90 includes a microcomputer having a known configuration such as a CPU, ROM, and RAM, and performs sequence control with the motor operation unit 82, the motor control unit 91, and the storage unit 92 provided in the operation unit 80. It has a PLC (Programmable Logic Controller) and the like. The motor operation unit 82 is responsible for operating the first servomotor 31 and the second servomotor 71. The motor control unit 91 numerically controls the first servomotor 31 and the second servomotor 71 to control the drive of the rotation direction, rotation speed, rotation amount, and the like. In addition to the program, the storage unit 92 stores data such as a set value of the number of pulses and an XY coordinate value. The electric control unit 90 is electrically connected to the motor operation unit 82 of the operation unit 80 that operates the drive to the first servomotor 31 and the second servomotor 71.

The motor control unit 91 is electrically connected to the first servomotor 31 and the second servomotor 71. The motor control unit 91 includes a controller and a servo driver, and performs drive control between the first servo motor 31 and the second servo motor 71 by a semi-closed loop method. The controller outputs an operation command (target value) to the servo driver, and the servo driver outputs a power signal following the controller command to the first servo motor 31 and the second servo motor 71 to drive the motor. To do. Further, the servo driver inputs a feedback signal from the encoder of the first servo motor 31 and the encoder of the second servo motor 71, and the controller inputs a feedback signal from the servo driver.

In addition to the motor control unit 91, the PLC includes a solenoid valve of a hydraulic unit that supplies hydraulic oil to the hydraulic cylinder 45, a solenoid valve that controls the flow rate of hydraulic oil in addition to the hydraulic unit, and an air cylinder 61 in the strain amount measuring unit 60. It is electrically connected to an electrical device equipped in the pressurized strain removing device 1, such as a solenoid valve that controls the operation of the rod 62.

The electric control unit 90 regards the upper surface 11 of the platen 10 as a plane of the XY coordinate system having the LR in the left-right direction as the "X-axis" and the FB in the front-rear direction as the "Y-axis", and the spindle head 40 with respect to the upper surface 11. And the position of the frame 20 are controlled by the XY coordinate values. Further, as shown in FIGS. 7 and 8, on the display 81 in the operation unit 80, the position information of the spindle head 40 with respect to the left-right direction LR of the beam portion 23 of the frame 20 is a surface plate with an “X reference value”. The position information of the frame 20 with respect to the front-rear direction FB of 10 is displayed by "Y standard value".

As shown in FIG. 7, in the motor operation unit 82 of the operation unit 80, the joystick lever 83 is operated by the first servomotor 31 to move the spindle head 40 in the X direction, and by the second servomotor 71, the frame 20. Is a function for performing an operation of moving the motor in the Y direction. The feed speed conversion switch 84 controls the drive of the first servomotor 31 and the drive of the second servomotor 71 to reduce the feed speed of the spindle head 40 and the feed speed of the frame 20 to high speed, medium speed, and low speed. Switch in 3 steps.

The hydraulic cylinder operation unit 85 of the operation unit 80 operates the rod 46 of the hydraulic cylinder 45 to move up and down. That is, in the straightening and lowering, the rod 46 is extended and the pressing head 54 is brought into contact with the surface Wa of the work W placed on the surface plate 10 to pressurize. The pressurizing time by the pressing head 54 can be set by a timer function provided in the electric control unit 90. In the straightening rise, the rod 46 is housed in the hydraulic cylinder 45, and the pressing head 54 is separated from the surface Wa of the work W placed on the surface plate 10 to release the pressurization. The measuring device operating unit 86 of the operating unit 80 shortens the rod 62 of the air cylinder 61 in the strain measuring unit 60, and brings the pressing head 54 into contact with the upper surface Wa of the work W placed on the surface plate 10. ..

By the way, in the actual strain removing work, there are cases where strained workpieces W having the same specifications are supplied to the work site in a certain number of lots, for example, several to a dozen pieces, and the strain removing work is performed. .. In addition, there may be a case where only one distorted work W such as a custom-made product is continuously brought to the work site at irregular intervals to perform the distorted work. In preparation for such a case, the pressure type strain removing device 1 stores an automatic operation program in the storage unit 92 of the electric control unit 90. FIG. 6 is an explanatory diagram exemplarily showing a pressure portion of a work placed on a surface plate of a pressure type strain removing device.

In the automatic operation program, among the work W placed on the surface plate 10, one or more pressurizing portions P to which the pressing force by the hydraulic cylinder 45 is applied (for example, in FIG. 6, the first to fifth measurement comparison positions P1 to P5). ), And the strain amount measuring unit 60 moves the frame 20 and the spindle head 40 directly above the measurement reference position (for example, the measurement reference position P0 in FIG. 6) in which the pressing head 54 is brought into contact with the surface Wa of the work W. It is a program to let and arrange. In the automatic operation program, for example, there are a plurality of work Ws shown in FIG. 6 having the same specifications, and when performing the strain removing work of these work Ws, all the pressurizing parts P (first to first) having the strained parts. It is possible to set and register the position information of the 5 measurement comparison positions P1 to P5) and the measurement reference position P0.

Further, the frame 20 and the spindle head 40 are first arranged directly above the measurement reference position P0, followed by the first measurement comparison position P1, the second measurement comparison position P2, and finally the fifth measurement comparison position P5. It is possible to set and register the order of placement. Further, since the measurement reference position P0 and the pressurizing portion P differ depending on the type of the work W, a plurality of types of automatic operation programs can freely set the measurement reference position P0 and the pressurizing portion P according to the specifications of the work W. It can be set, registered and saved.

Further, in the electric control unit 90, as shown in FIG. 1, until the spindle head 40 is arranged on the virtual vertical line M that passes through the specific point Q on the upper surface 11 of the platen 10 along the vertical VT. The control unit 90 can store in the storage unit 92 electrical information regarding the movement of the first servomotor 31 accompanying the movement of the frame 20 and the movement of the second servomotor 71 accompanying the movement of the spindle head 40. It has become. At the specific point Q, when the spindle head 40 is arranged on the pressurizing portion P and the pressing head 54 is brought into contact with the pressurizing portion P of the work W to pressurize, or when the spindle head 40 is arranged on the measurement reference position P0. When the pressing head 54 is brought into contact with the measurement reference position P0 of the work W and the reference distance described later is measured, the positional relationship of the spindle head 40 is XY coordinates with respect to the upper surface 11 of the surface plate 10. It is a point defined by the coordinate value of the system (see FIG. 8).

The procedure for performing the strain removing work with the pressurized strain removing device 1 will be described. As shown in FIG. 6, the operator sets a reference portion to be positive at the time of measurement as a measurement reference position (for example, P0 shown in FIG. 6) with respect to the upper surface Wa of the work W including distortion. Next, the operator visually confirms the existence of a strained portion generated on the surface Wa of the work W at a portion different from the measurement reference position P0, and determines this strained portion at the measurement contrast position (in the present embodiment, the figure). No. 6 is set as the first measurement comparison position P1, the second measurement comparison position P2, the third measurement comparison position P3, the fourth measurement comparison position P4, and the fifth measurement comparison position P5).

The measurement reference position P0 is a portion where the strain amount is zero (or a strain amount within the permissible range and a magnitude close to zero), and is a “positive” region in measurement, and the first to fifth measurement comparison positions P1 to This is a reference position that can be a relative origin with P5. When the pressing head 54 descends toward the measurement reference position P0, the relative displacement (reference distance) of the rod 62 of the air cylinder 61 due to the movement is changed between the display unit 66 of the strain amount measurement unit 60 and the operation unit 80. It is displayed on the display 81.

Next, the operator once returns the rod 62 of the air cylinder 61 to the origin position, then moves the frame 20 and the slide portion 41 as necessary, lowers the rod 62 again, and pushes the pressing head 54. It is brought into contact with the first strained portion (first measurement contrast position P1). Then, when the pressing head 54 descends toward the first measurement comparison position P1, the relative displacement (comparative distance) of the rod 62 of the air cylinder 61 accompanying the movement is displayed on the display unit 66 and the display 81.

Next, the operator confirms the height difference (distance difference) between the displayed reference distance with respect to the measurement reference position P0 and the displayed contrast distance with respect to the first measurement contrast position P1. Next, the operator propels the rod 46 of the hydraulic cylinder 45 downward while keeping the pressing head 54 in contact with the first measurement comparison position P1, so that the height difference approaches 0 as much as possible. The pressing force of 45 is transmitted to the pressing head 54 via the second support plate 49.

For each of the second to fifth measurement comparison positions P2 to P5, the pressing head 54 is brought into contact with the second measurement comparison position P2 and the like in the same manner as in the first measurement comparison position P1, and the operator can perform the second measurement comparison position. The relative displacement (contrast distance) of the rod 62 of the air cylinder 61 due to the descent toward the measurement contrast position P2 or the like is confirmed by the display unit 66 and the display 81. Then, the operator propels the rod 46 of the hydraulic cylinder 45 downward while keeping the pressing head 54 in contact with the second measurement comparison position P2 or the like, and the height difference (distance difference) between the reference distance and the comparison distance. ) Is transmitted to the pressing head 54 via the second support plate 49 so that the pressing force of the hydraulic cylinder 45 approaches 0 as much as possible. Thus, the pressurized strain removing device 1 of the present embodiment measures the amount of strain and removes the strain at the strained portion.

Next, the operation and effect of the pressurized strain removing device 1 according to the present embodiment will be described. The pressure type strain removing device 1 according to the present embodiment has a portal shape that straddles the left-right direction LR of the platen 10 on which the work W is placed and can move in the front-back direction FB orthogonal to the left-right direction LR and the up-down direction VT. The frame 20 and the hydraulic cylinder 45 for generating a pressing force are provided, and the spindle head 40 is slidably suspended and suspended from the beam portion 23 of the frame 20, and the hydraulic cylinder 45 is a beam of the frame 20. In the pressurized strain removing device detachably attached to the spindle head 40 on the lower side from the portion 23, the first servomotor 31 which is a power source when the frame 20 moves and the power source when the spindle head 40 moves. A second servomotor 71 and an electric control unit 90 for controlling the first servomotor 31 and the second servomotor 71 are provided, and the electric control unit 90 is a first servomotor 31 and a second servomotor 71. Motor operation unit 82 (operation unit 80) for operation, motor control unit 91 for numerical control to drive the first servomotor 31 and second servomotor 71, and electrical information controlled by the motor control unit 91. It is characterized by having a storage unit 92 capable of storing the above.

Due to this feature, the operator performs the setup work for arranging the spindle head 40 at the strained portion of the strained work W each time the strained work W is performed one by one. The process of arranging the spindle head 40 and the spindle head 40 on the pressurizing portion P of the work W can be automatically and easily performed simply by operating the operation unit 80 regardless of the number of strained work W. .. In addition, the burden on the operator for the strain removing work is significantly reduced as compared with the pressure type strain removing device of Patent Document 1 in which all the setup work is performed by the operator one by one with the strained work W. it can.

Further, when the strain-removing work W is first subjected to the strain-removing work, then the strain-removing work W having the same specifications is also subjected to the distortion-removing work, or the strain-removing work is performed first. After the work W, the strain removing work of the strained work W having the same specifications as the strained work W may be performed after a certain period of time, for example, several days or several months. In such a case, in the setup work of the strained work W where the distortion removing work is performed, the movement of the first servomotor 31 accompanying the movement of the frame 20 and the second servomotor accompanying the movement of the spindle head 40 When the electrical information regarding the movement of the 71 is stored in the storage unit 92, the setup work to be performed for the next distortion removing work of the distorted work W is the first servomotor stored in the storage unit 92. This can be done based on the movement of 31 and the movement of the second servomotor 71. Therefore, when a plurality of strained work Ws have the same specifications, it is possible to save the labor of the operator in performing the setup work of the strain removing work.

Therefore, according to the pressure type strain removing device 1 according to the present embodiment, the strain generated in the strained work W can be efficiently removed by improving the workability related to the strain removing work. Has an effect.

Further, in the pressure type strain removing device 1 according to the present embodiment, the electric control unit 90 is a true pressure portion P of one or more of the work W placed on the surface plate 10 to which the pressing force by the hydraulic cylinder 45 is applied. It is characterized in that an automatic operation program for moving and arranging the frame 20 and the spindle head 40 is stored in the storage unit 92. Due to this feature, when a plurality of distorted workpieces W have the same specifications, the setup work itself can be performed efficiently, and the time required for the setup work is, for example, 1/2 or less of that of the conventional one. Since it can be shortened significantly, the productivity of distortion removal work is dramatically improved.

That is, as described above, when the strained work W having the same specifications is supplied to the work site in a certain number of lots, for example, several to a dozen pieces, or when the strain is removed by a custom-made product. There is a case where only one such strained work W is continuously brought to the work site intermittently at intervals to perform the distortion removing work. In such a case, in particular, the operator operates the operation unit 80 to arrange the frame 20 and the spindle head 40 on the pressurizing portion P of the work W in performing the setup work. Therefore, the process content can be simplified. Further, even an operator who is unfamiliar with the setup work can easily perform such the setup work without any discomfort. Further, in recent years, there is a problem in the industrial world that there is a shortage of human resources for workers and a shortage of successors to hand down the technology, but the pressurized strain removing device 1 efficiently performs the strain removing work. Since it can be done, it can contribute as one of the solutions to such problems.

Further, the pressurized strain removing device 1 according to the present embodiment is characterized by including a strain amount measuring unit 60 capable of quantitatively grasping the state of strain held in the work W. Due to this feature, when the strain of the work W is removed by the pressing force of the hydraulic cylinder 45, the magnitude of the strain can be easily grasped by the strain amount measuring unit 60 at the position where the pressing force is applied to the work W. Therefore, it is possible to reasonably and efficiently grasp the amount of strain and apply the pressing force of the hydraulic cylinder 45 required for removing the strain at the strained portion. Therefore, in performing the strain removing work, the setup work can be further simplified.

In particular, when the strained portions are dispersed over a plurality of locations on the work W placed on the upper surface 11 of the surface plate 10, the strain removing work is sequentially performed for each of the plurality of strained portions. When doing so, it is possible to reasonably and easily grasp the amount of strain and remove the strain by pressurization at each strain portion by simply moving the frame 20 and the spindle head 40 as needed. Therefore, it is possible to reduce the work load on the operator for the strain removing work. Further, since the productivity of the strain removing work is improved, it is possible to contribute to the reduction of the processing cost for performing the strain removing.

Although the present invention has been described above in accordance with the embodiment, the present invention is not limited to the above embodiment, and can be appropriately modified and applied without departing from the gist thereof.

(1) For example, in the embodiment, a stepping motor having an encoder and a brake built-in is used as the drive source of the spindle head 40 (first servomotor 31) and the drive source of the frame 20 (second servomotor 71), respectively. However, the first servomotor and the second servomotor of the present invention may be servomotors that can be controlled in a fully closed loop system by computerized numerical control (CNC).
(2) In the embodiment, the frame 20 is moved under the frame feed mechanism 30, and the spindle head 40 is moved under the spindle head feed mechanism 70. However, instead of the frame feed mechanism 30 and the spindle head feed mechanism 70, the frame transmits the drive of the first servomotor to the ball screw to move it, and the spindle head transmits the drive of the second servomotor to the ball screw. It may be moved by.

(3) In the embodiment, the pressure type strain removing device 1 for removing the strain of the work W by applying the pressing force of the hydraulic cylinder 45 downward in the vertical direction has been described. However, in the pressure type strain removing device of the present invention, an attachment is attached to the spindle head, and the pressing force of the rod of the hydraulic cylinder attached to the attachment is applied in the horizontal direction to remove the strain of the workpiece. It may be configured to have a pressing function.
(4) In the embodiment, in the work W, the height difference between the measurement contrast position, which is a strain portion, and the measurement reference position is confirmed by the strain amount measuring unit 60, and the height difference is manually adjusted to approach 0 as much as possible. The pressing force of the hydraulic cylinder 45 was applied to the measurement contrast position to remove the strain. However, the pressurization type strain removing device of the present invention automatically adjusts the pressurization amount by the hydraulic cylinder after linking the height difference between the measurement comparison position and the measurement reference position with the measurement data obtained by the strain amount grasping means. The strain of the workpiece may be removed by controlling with.

1 Pressurized strain removing device 10 Surface plate 11 (Surface plate) Top surface 20 Frame 23 Beam 31 First servo motor (first servo motor)
40 Spindle head 45 Hydraulic cylinder 60 Strain amount measuring unit (strain amount grasping means)
71 Second servo motor (second servo motor)
80 Operation unit 82 Motor operation unit 90 Electrical control unit (control means)
91 Motor control unit 92 Storage unit M Virtual perpendicular line P Pressurized part Q Specific point W Work (workpiece)
FB Front-back direction LR Left-right direction VT Up-down direction

Claims (3)

It has a portal-shaped frame that straddles the left-right direction of the platen on which the workpiece is placed and can move in the front-back direction that is orthogonal to the up-down direction and the left-right direction, and a hydraulic cylinder that generates pressing force.
The spindle head is slidably suspended from the beam portion of the frame, and the hydraulic cylinder is a pressure type strain removing device detachably attached to the spindle head on the lower side from the beam portion of the frame. In
A first servomotor that serves as a power source for the movement of the frame,
A second servomotor that serves as a power source for the movement of the spindle head,
A control means for controlling the first servomotor and the second servomotor is provided.
The control means includes a motor operation unit that operates the first servomotor and the second servomotor, and a motor control unit that numerically controls the drive of the first servomotor and the second servomotor. And having a storage unit capable of storing electrical information controlled by the motor control unit.
Pressurized strain removing device characterized by. In the pressurized strain removing device according to claim 1,
The control is a program for moving and arranging the frame and the spindle head directly above one or more pressurizing portions to which a pressing force is applied by the hydraulic cylinder among the workpieces placed on the surface plate. Being stored in the storage unit of the means,
Pressurized strain removing device characterized by. In the pressurized strain removing device according to claim 1 or 2.
Equipped with a strain amount grasping means that can quantitatively grasp the state of strain possessed by the work piece,
Pressurized strain removing device characterized by.

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