The present invention relates to a press brake, and particularly, to a press brake provided with a function of correctly detecting an amount of vertical deflection (strain) on left and right side frames of the press brake.
As is well known, a press brake has an upper table at upper part of left and right side frames having a C-gap. To face the upper table in a vertical direction, the press brake has a lower table at lower part of the left and right side frames. A proper one of the upper and lower tables serves as a ram that is movable vertically. To vertically move the ram, the side frames are provided with left and right vertical driving units, respectively. An amount of vertical strain (deflection) on the left and right side frames is detected to compute pressing force applied by the vertical driving units. Based on a result of the computation, the pressing force of the vertical driving units is controlled. Related arts are, for example, Japanese Unexamined Patent Application Publications No. H05-57353 (Patent Literature 1) and No. H07-24530 (Patent Literature 2).
The configuration described in the Patent Literature 1 arranges a bending load detector on an inner side face of the left and right side frames adjacent to the C-gap. More precisely, the bending load detector is arranged at a position where a tangential line of the C-gap is vertical, i.e., a position where deflection to occur is small when the side frames are vertically deflected to open the C-gap. Since the bending load detector is arranged on an inner side face of the side frames, the detector also detects horizontal deflection that occurs when the side frames are horizontally deflected due to, for example, vibration at the time of vertical acceleration or deceleration of the ram. It is difficult for the related art to detect only the vertical deflection of the side frames.
The configuration described in the Patent Literature 2 arranges, as is apparent in
In consideration of the above-mentioned problems, the present invention provides a press brake having a lower table arranged at lower part of left and right side frames, an upper table arranged at upper part of the side frames and facing the lower table, one of the upper and lower tables serving as a ram to be moved vertically, and left and right vertical driving units arranged on the side frames, respectively, to move the ram vertically. The press brake is characterized in that strain detecting sensors are arranged on inner and outer side faces, respectively, of each of the left and right side frames, to detect strain of the side frames.
Referring to
In the above configuration, upper and lower dies 8P and 8D attached to the upper and lower tables 7 and 9 are driven to bend a plate work W. In order to detect an amount of deflection (strain) of each of the left and right side frames 5L and 5R, outer and inner side faces of the left and right side frames 5L and 5R are provided with strain detecting sensors 15A, 15B, 15C, and 15D, respectively. On the left side frame 5L, the strain detecting sensor 15A attached to the outer side face and the strain detecting sensor 15B attached to the inner side face form a pair. Similarly, the strain detecting sensors 15C and 15D attached to the right side frame 5R are conjugate.
The strain detecting sensors 15A, 15B, 15C, and 15D arranged on the outer and inner side faces of the left and right side frames 5L and 5R are at horizontally symmetrical positions with the left and right side frames 5L and 5R interposed between them. In other words, the outer and inner strain detecting sensors 15A and 15B and 15C and 15D are positioned to face each other in each pair. The strain detecting sensors 15A, 15B, 15C, and 15D are arranged at positions where the side frames 5L and 5R are subject to be deflected when the upper and lower dies press the work.
More precisely, as illustrated in
The locations where strain gauges of the strain detecting sensors 15A to 15D are arranged must be flat to detect strain. Such a flat location must have a certain precision flatness. To attach the strain detecting sensors 15A to 15D to the left and right side frames 5L and 5R, the inner and outer side faces of the side frames 5L and 5R may each be cut or ground to form a precision flat measuring area. Forming such a precision flat measuring area on each of the inner and outer side faces of the side frames 5L and 5R is rather difficult, and therefore, the embodiment employs the below-mentioned configuration.
The strain detecting sensors 15A to 15D each have, as illustrated in
The support block 25 is in a recess formed in a biasing member 27, is restricted to move in a direction normal to the plane of the drawing and in a vertical direction, and is biased by the biasing member 27 with a predetermined biasing force. The biasing member 27 is biased by a predetermined pushing force produced by a resilient member 31 such as a coil spring arranged between the biasing member 27 and a fitting bolt 29 that is passed through the biasing member 27 and screwed into the strain measuring plate 21. The strain gauge 23, therefore, is biased toward the measuring flat surface 21F of the strain measuring plate 21 with the set predetermined pushing force applied by the resilient member 31.
As is already understood, the pushing force on the strain gauge 23 toward the measuring flat surface 21F of the strain measuring plate 21 is always constant. The strain measuring plate 21 with the strain gauge 23 biased toward the measuring flat surface 21F is fitted to each of the inner and outer side faces of the side frames 5L and 5R with the fixtures 19. Namely, under the same condition that the strain gauge 23 is biased with the predetermined pushing force toward the measuring surface 21F of the strain measuring plate 21, the strain detecting sensors 15A to 15D are fitted to the side frames 5L and 5R. Namely, the strain detecting sensors 15A to 15D are easily attachable in the same condition to the inner and outer side faces of the left and right side frames 5L and 5R.
The threaded part of each fitting bolt 29 may be elongated so that the fitting bolt 29 is passed through the strain measuring plate 21 and directly fastened to the side frame 5L (5R). In this case, the fixtures 19 are omissible to simplify the structure.
Strain on the side frames 5L and 5R is detected to control outputs from the vertical driving units 11L and 11R. For this, a control unit 33 (refer to
The control unit 33 also includes set value memories 37A and 37B to store preset outputs for the vertical driving units 11L and 11R. Further, the control unit 33 includes comparison units 39A and 39B to compare computed results from the computing units 35A and 35B with the set values in the settings memories 37A and 37B. The comparison units 39A and 39B have functions of comparing computed results from the computing units 35A and 35B with the set values stored in the settings memories 37A and 37B and controlling outputs of the vertical driving units 11L and 11R to be equal to the set values stored in the settings memories 37A and 37B.
With the above-mentioned configuration, the left and right vertical driving units 11L and 11R are driven to press the work W with the upper and lower dies 8P and 8D. Reactive force of the pressing vertically deflects (strains) the side frames 5L and 5R. Amounts of strain on the side frames 5L and 5R are detected by the strain detecting sensors 15A, 15B, 15C, and 15D. According to the detected strain amounts, pressing force by each of the vertical driving units 11L and 11R is computed, to control outputs of the vertical driving units 11L and 11R to required values.
When the vertical driving units 11L and 11R are driven to vertically move the upper table 7, vibration tends to occur during acceleration or deceleration to oscillate the left and right side frames 5L and 5R in left and right directions in
According to the configuration that arranges a strain detecting sensor on only one of the outer and inner side faces of the side frames 5L and 5R, only one of the detected values (A) and (B) illustrated in
On the other hand, the strain detecting sensors 15A to 15D of the present embodiment is arranged on the inner and outer side faces of the left and right side frames 5L and 5R, and therefore, is able to simultaneously detect contraction and elongation caused by horizontal deflection of the left and right side frames 5L and 5R and compute an average of values detected by the inner and outer strain detecting sensors 15A and 15B as illustrated in
The present invention is not limited to the above-mentioned embodiment. It allows proper modifications to realize other embodiments. For example, locations of the strain detecting sensors 15A to 15D are not limited to those under the C-gap 3. As illustrated with an imaginary line in
According to the present invention, a press brake is provided with strain detecting sensors on inner and outer side faces of left and right side frames of the press brake. When the side frames deflect horizontally, one of the strain detecting sensors that form a pair detects elongation of the corresponding side frame and the other detects contraction of the same. Values detected by the pair of strain detecting sensors are used to cancel the horizontal deflection and detect an amount of vertical deflection.
In connection with United States designation, this international patent application claims the benefit of priority under 35 U.S.C. 119(a) to Japanese Patent Application No. 2014-033970 filed on Feb. 25, 2014 whose disclosed contents are incorporated herein by reference.
Number | Date | Country | Kind |
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2014-033970 | Feb 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/053732 | 2/12/2015 | WO | 00 |