The present invention relates to a press forming method for a workpiece material which is made of steel, and a tool for press forming which is used in the press forming method.
Priority is claimed on Japanese Patent Application No. 2014-103735, filed on May 19, 2014, the content of which is incorporated herein by reference.
As a method for forming a final product such as a bottomed cylindrical member having a vertical wall portion and a bottom wall portion which is continuous with the vertical wall portion from a plate-shaped material, a cup-shaped intermediate material, or the like, a drawing method is widely used.
For example, Non-Patent Document 1 discloses a method which forms a cylindrical container having a constant inner diameter from a bottom portion to an opening portion, or a stepped cylindrical product having a step portion in which an inner diameter changes on the way from the bottom portion to the opening portion. That is, in general, a method is widely used, in which an intermediate material which is formed into a cup shape from a disk-shaped material in a first process is drawn in a second process again, and the cup-shaped intermediate material is further drawn by the re-drawing method.
In this re-drawing method, the cup-shaped intermediate material formed in the first process is nipped between a die in which the intermediate material is accommodated, and a blank holder which is a cylindrical tool inserted into the inner portion of the intermediate material. In addition, a punch coaxially passing through the inner portion of the blank holder is pushed to be inserted into a columnar space which is formed on the bottom of the die, and a cylindrical protrusion is formed on the bottom wall portion of the cup-shaped intermediate material. However, in this forming method, the material configuring the bottom wall portion of the cup-shaped intermediate material may not be sufficiently fed into the columnar space by the punch. In this case, there are problems that the bottom wall portion of the intermediate material may be broken by the tip angle portion of the punch, and a forming failure due to insufficient supply of a material into the columnar space may occur.
With respect to the above-described problems, in Patent Document 1, Non-Patent Document 1, and Non-Patent Document 2, a method for preventing a forming failure using a tool divided into multiple portions is disclosed. That is, as with the re-drawing method of the related art, the upper edge portion of the intermediate material is pressed by the second punch while the first punch is pushed into the bottom wall portion of the cup-shaped intermediate material so as to form a cylindrical protrusion. According to this method, supply of a material into the periphery of the tip angle portion of the first punch is promoted due to a pressing force by the second punch, and as a result, it is possible to prevent a forming failure due to a material breakage or the like.
In addition, Patent Document 2 discloses a method in which forming is not performed on a cup-shaped intermediate material, and a final product is obtained from a plate-shaped material by a single process.
In these forming methods, in order to perform forming in a state where a forming failure does not occur, it is important to maintain the movement speed of each tool divided into multiple portions (for example, first punch and second punch) at an appropriate value. In this case, in consideration of variation in material dimensions before forming, or variation in lubrication states between the tool and the material during the forming, it is preferable to proceed forming while the movement speed of each portion of the tool is suitably corrected to an appropriate value according to the forming progress situation such as filling of the material into the tool.
Patent Documents 3 to 5 disclose a method and a device for measuring a load distribution or a strain amount in a tool during press forming. However, in a forming method which is used in general, forming is only performed while each tool divided into multiple portions moves at a constant speed which is set in advance before shaping starts. Accordingly, the movement speed is not corrected according to the material dimensions or the progress situation of press forming during forming.
[Patent Document 1] Japanese Unexamined Patent Application, First Publication No. 2004-322104
[Patent Document 2] Japanese Unexamined Patent Application, First Publication No. 2010-214381
[Patent Document 3] Japanese Unexamined Patent Application, First Publication No. 2008-149349
[Patent Document 4] Japanese Unexamined Patent Application, First Publication No. 2008-173686
[Patent Document 5] Japanese Unexamined Patent Application, First Publication No. 2010-115702
[Non-Patent Document 1] Takashi SUZUMURA, JOURNAL OF THE JAPAN SOCIETY FOR TECHNOLOGY OF PLASTICITY, P. 9, vol. 51, No. 594 (2010)
[Non-Patent Document 2] Michiharu YOKOI, JOURNAL OF THE JAPAN SOCIETY FOR TECHNOLOGY OF PLASTICITY, P 13, vol. 51, No. 594 (2010)
In the above-described press forming method, if a movement speed ratio between a first punch and a second punch which move independently from each other during forming is not appropriate, a load of any one of the two punches becomes excessive, the load may exceed a forming load limit of the drawing device, and there is a concern that further forming may be impossible.
On the contrary, although both loads of the first punch and the second punch are within the forming load limit of the drawing device, an unfilled portion where the tool is not filled with a material remains, and as a result, there is a concern that a forming failure of a product may occur.
The present invention is made in consideration of the above-described circumstances, and an object thereof is to provide a press forming method and a tool for press forming in which it is not impossible to perform forming if a forming load exceeds a load limit of a press forming device when each portions of a tool divided into multiple portions are operated independently from each other, and a product in which a forming failure due to unfilling the tool with a material does not occur can be stably formed .
In order to solve the problem and achieve the object, the inventors investigated a method for ascertaining a material inflow at a predetermined position inside a tool in a non-contact manner. In addition, as an example of the method, the inventor adopted a method which provides a sensor in the tool for measuring deformation of the tool, measures a deformation amount generated in the tool by the sensor, and detects an overload situation of the tool during forming. According to this method, it is possible to prevent the load applied to the tool from excessively exceeding the load limit of the press forming device so as not to be impossible to perform forming, and it is possible to prevent a forming failure of a product associated with the unfilling the tool with a material.
That is, the primary points of the present invention are as follows.
(1) According to an aspect of the present invention, there is provided a press forming method, including: a first process of obtaining a pressing force applied to each portion of a tool by an workpiece material during press forming while independently driving the respective each portion of the tool divided into multiple portions and press forming the workpiece material; and a second process of adjusting at least one of an applied driving force, an applied driving speed, and an applied driving timing for each portion of the tool to cause a processing portion of the workpiece material in which the state approaching an overload state is detected based on the pressing force to flow to other processing portions of the workpiece material.
(2) In the aspect according to (1), in the first process, the pressing force may be obtained based on a deformation amount of the tool generated according to the flow of the workpiece material during press forming.
(3) In the aspect according to (1) or (2), in the second process, whether or not the state has approached the overload state may be determined by whether or not the pressing force exceeds a predetermined threshold value.
(4) In the aspect according to any one of (1) to (3), press forming may be drawing for forming the workpiece material into a cylindrical member having an axis line, and the pressing force may be obtained at multiple locations along a circumferential direction of which the center is the axis line.
(5) In the aspect according to any one of (1) to (3), press forming may be drawing for forming the workpiece material into a cylindrical member having an axis line, and the pressing force may be obtained at multiple locations along an extension direction of the axis line.
(6) In the case of (5), the pressing force may be further obtained at multiple locations along a circumferential direction of which the center is the axis line.
(7) In the aspect according to any one of (1) to (6), the tool may include a die and a punch, and the pressing force may be obtained by a strain sensor which is provided on at least one of the die and the punch.
(8) In the aspect according to any one of (1) to (7), a preliminary process may be performed before the first process, and the preliminary processing may include: a calculation process of obtaining a prediction correspondence relationship between at least one of the driving force, the driving speed, and the driving timing, and the pressing force in which the overload state is not generated, in numerical calculations; a measurement process of measuring the pressing force applied to each portion of the tool by the workpiece material during forming while independently driving the respective each portions of the tool and press forming the workpiece material according to the prediction correspondence relationship obtained by the calculation process, and obtaining a measurement correspondence relationship between the measured pressing force and at least one of the driving force, the driving speed, and the driving timing; and a correction process of obtaining a difference between the prediction correspondence relationship obtained by the calculation process and the measurement correspondence relationship obtained by the measurement process, and correcting the prediction correspondence relationship, in which the first process may be performed according to the corrected prediction correspondence relationship obtained by the preliminary process.
(9) According to another aspect of the present invention, there is provided a tool for press forming including a tool divided into multiple portions in which each portion individually receives a driving force and press forms an workpiece material; in which a sensor which acquires a pressing force which is applied to a forming surface of the tool from the workpiece material during press forming.
(10) In the aspect according to (9), a configuration may be adopted, in which the tool for press forming is used for drawing so that the workpiece material is formed into a cylindrical member having an axis line, and the sensor is provided at multiple locations along a circumferential direction of which the center is the axis line.
(11) In the aspect according to (9), a configuration may be adopted, in which the tool for press forming is used for drawing so that the workpiece material is formed into a cylindrical member having an axis line, and the sensor is provided at multiple locations along an extension direction of the axis line.
(12) In the case of (11), the sensors may be further provided at multiple locations along a circumferential direction of which the center is the axis line.
(13) In the aspect according to any one of (9) to (12), a configuration may be adopted, in which the tool for press forming includes a die and a punch, and the sensor is a strain sensor which is provided on at least one of the die and the punch.
(14) In the case of (13), a detection unit of the strain sensor may be provided at a position at a depth of 5 mm to 50 mm from the forming surface of at least one of the die and the punch on which the strain sensor is provided.
According to the aspect described in (1) of the present invention, after the flow state in the material of the workpiece material in the tool is ascertained based on the pressing force acquired by the first process, it is possible to control the operation of each portion of the tool in the second process. Accordingly, it is not impossible to perform forming if a forming load exceeds a load limit of a press forming device when each portions of a tool are operated independently from each other, and it is possible to perform press forming a product in which a forming failure due to unfilling the tool with a material does not occur.
In the case of (2), since the flow in the material of the workpiece material can be ascertained with favorable responsiveness, even when press forming is performed in a short time, it is possible to secure a time required for controlling the driving of each portion of the tool, and it is possible to accurately perform press forming of the workpiece material.
In the case of (3), it is possible to control the operation of each portion of the tool, when the flow state of the workpiece material during press forming is instantaneously determined.
In the case (4), since pressing forces are obtained at multiple locations along the circumferential direction of which the center is the axis line, it is possible to reliably prevent failed operations due to variation in the flow states of the workpiece material in the circumferential direction.
In the case (5), since pressing forces are obtained at multiple locations along the extension direction of the axis line, it is possible to ascertain the forming process of the workpiece material with higher sensitivity. In addition, an application can be performed, in which data of the pressing forces obtained along the axis line direction is input to a numerical calculation model so that press forming is simulated to increase calculation accuracy.
In the case of (6), since the pressing forces are obtained both along the extension direction of the axis line and the circumferential direction thereof, it is possible to three-dimensionally ascertain the forming process of the workpiece material.
In the case of (7), since the flow of the workpiece material can be ascertained with appropriate sensitivity and responsiveness by the strain sensor, it is possible to more accurately perform press forming of the workpiece material.
In the case of (8), since the first process and the second process can be performed, when at least one of the driving force, the driving speed, and the driving timing is optimized by the preliminary process, it is possible to more accurately perform press forming.
According to the aspect described in (9) of the present invention, it is possible to ascertain the flow state of the material of the workpiece material in the tool based on the pressing force acquired by the sensor. Accordingly, it is not impossible to perform forming if a forming load exceeds a load limit of a press forming device when each portions of a tool are operated independently from each other, and it is possible to control so as to be stably drawn a product in which a forming failure due to unfilling the tool with a material does not occur.
In the case of (10), since the pressing forces can be obtained at multiple locations along the circumferential direction of which the center is the axis line, it is possible to reliably prevent failed operations due to variation in the flow states of the material of the workpiece material in the circumferential direction.
In the case of (11), since the pressing forces are obtained at multiple locations along the extension direction of the axis line, it is possible to ascertain the forming process of the workpiece material with higher sensitivity. In addition, an application can be performed, in which data of the pressing forces obtained along the axis line direction is input to a numerical calculation model so that press forming is simulated to increase calculation accuracy.
In the case of (12), since the pressing forces are obtained both along the extension direction of the axis line and the circumferential direction thereof, it is possible to three-dimensionally ascertain the forming process of the workpiece material.
In the case of (13), since the flow in the material of the workpiece material can be ascertained with favorable responsiveness by the strain sensor, even when press forming is performed in a short time, it is possible to secure a time required for controlling the driving of each portion of the tool, and it is possible to accurately perform press forming of the workpiece material.
In the case of (14), measurement can be accurately performed within a sensitivity range of the strain sensor.
Each embodiment of a press forming method and a tool for press forming of the present invention will be described below.
In each embodiment, in a drawing method using a press forming device capable of independently operating each portions of the tool divided into multiple portions, after an overload situation of a tool during forming is detected based on output signals corresponding to a deformation amount of the tool measured by a sensor for measuring deformation of the tool using the tool into which the sensor is inserted, a movement speed ratio or the like of each portion of the tool divided into multiple portions is appropriately controlled according to the overload situation.
In addition, according to the control, it is possible to prevent continuous forming from being impossible due to an excessive load exceeding the limit of the press forming device, or it is possible to prevent a forming failure of a product associated with the unfilling the tool with a material. As a result, the inside of the tool is filled with a plate-shaped material, a cup-shaped intermediate material, or the like, and it is possible to obtain a product in which each portion of the material has a predetermined plate thickness and a predetermined shape.
As shown in
As described above, among each portion of a tool divided into multiple portions, the movement of each of the punch 2, the blank holder 3, the outer circumferential punch 4, and the counter punch 6 is controlled by a press forming device having a drive mechanism which can individually and independently control the movements of the punch 2, the blank holder 3, the outer circumferential punch 4, and the counter punch 6, as a result, the material 1 is formed in a shape having a predetermined dimension.
The press forming device of the present embodiment includes a punch drive unit 21, a blank holder drive unit 22, an outer circumferential punch drive unit 23, and a counter punch drive unit 24 as the drive mechanism. The punch drive unit 21 drives the punch 2 based on a drive control signal output from the controller 10. The blank holder drive unit 22 drives the blank holder 3 based on a drive control signal output from the controller 10. The outer circumferential punch drive unit 23 drives the outer circumferential punch 4 based on a drive control signal output from the controller 10. The counter punch drive unit 24 drives the counter punch 6 based on a drive control signal output from the controller 10. Each of the above-described drive control signals includes a speed change signal, a stop signal, or the like. Accordingly, the starts or the stops of the movements of the punch 2, the blank holder 3, the outer circumferential punch 4, and the counter punch 6 are individually controlled. Similarly, the movement speeds or the movement stops of the punch 2, the blank holder 3, the outer circumferential punch 4, and the counter punch 6 are individually changed based on the speed change signals output from the controller 10.
The sensor 7 of the present embodiment is embedded into an assumed portion at which the inside of the tool is filled with the material 1 according to the progress of forming. For example, as shown in
Accordingly, the position at which the sensor 7 is disposed or the number of the sensors 7 may be appropriately changed according to the shape, the division configuration, or the like of the tool which performs press forming.
A drawing method (press forming method) using the tool and the press forming device having the above-described configuration will be described with reference to
First, the punch 2, the blank holder 3, and the outer circumferential punch 4 are lifted to standby positions having predetermined heights by driving the punch drive unit 21, the blank holder drive unit 22, and the outer circumferential punch drive unit 23.
Subsequently, the cup-shaped material 1 (intermediate material) is inserted from a gap provided between the punch 2, the blank holder 3, and the outer circumferential punch 4, and the die 5 which is positioned at the standby positions, and the cup-shaped material 1 is installed inside the die 5 such that the center axis line of the cup-shaped material 1 approximately coincides with the center axis line of the forming surface inside the die 5. Here, the cup shape is a bottomed cylindrical shape. Thereafter, the punch 2, the blank holder 3, and the outer circumferential punch 4 are integrated, and are lowered toward the material 1 which is disposed inside the die 5. Accordingly, the bottom wall portion 1a of the cup-shaped material 1 is nipped and pressed by the upper and lower surfaces of the blank holder 3, the punch 2, and the die 5 between the blank holder 3 and the punch 2, and the die 5, and the outer circumferential punch 4 comes into contact with an upper edge surface 1c of the cup-shaped material 1 and is stopped.
In this way, simultaneously with the movements of the punch 2, the blank holder 3, and the outer circumferential punch 4, the counter punch 6 lifts along the through hole 5a machined inside the cylindrical die 5, comes into contact with the bottom surface of the cup-shaped material 1, and is stopped. When the operations of each portion of the tool are completed, as shown in
In addition, when the material 1 is fixed to the inside of the die 5 by pressing the material 1 using the punch 2, the blank holder 3, and the outer circumferential punch 4, the bottom wall portion 1a of the material 1 is extruded downward while the punch 2 is further lowered, and the counter punch 6 is also lowered according to the movement. Accordingly, as shown in
The outer circumferential punch 4 is also lowered during press forming, and the upper edge surface 1c of the cup-shaped material 1 is pressed by the protrusion 4a to promote inflow of the material 1 inside the die 5. Accordingly, for example, as shown in
With respect to the reasons why the forming load largely increases according to the operation conditions of the outer circumferential punch 4 during press forming, the following matters are considered.
In general, before press forming is performed, a gap is provided between the material 1 and the die 5, and a gap is provided between the material 1 and the blank holder 3. If a gap is not provided between the material 1 and the die 5, before the material 1 is installed at a predetermined position inside the die 5, and a fitting state in which the material 1 and the die 5 engage with each other occurs. Accordingly, the material 1 cannot further move, and it is difficult to cause the material 1 to enter the predetermined position.
In addition, when the material 1 is forcibly moved in a state where a sufficient gap is not provided between the surface of the material 1 and the forming surface inside the tool, an uneven contact state may occur, in which only the end portion of the material 1 comes into contact with the tool in a state where the material 1 is inclined with respect to a standard posture. In this state, when the material 1 forcedly moves in the tool, there is a problem that the material 1 or the tool may be damaged. In addition, the force locally applied to the tool excessively increases, damages such as cracks may occur in the tool. In order to avoid the above-described problem, the material 1 which is press formed is designed to have a shape and dimensions in which a predetermined gap can be secured between the material 1 and the forming surface of the tool.
In press forming for obtaining a product having predetermined dimensions and a predetermined shape from the material 1, when the outer circumferential punch 4 is lowered to press the upper edge surface 1c of the material 1, the material 1 flows into the die 5, and it is possible to prevent breakage on the tip angle portion of the punch 2. However, when the material 1 is excessively pushed into the die 5 by the lowering of the outer circumferential punch 4, after the gap between the forming surface of the tool and the surface of the material 1 is filled with the material, the pressing by the outer circumferential punch 4 is continuously performed. As a result, the material is further forcibly fed to the portion which is filled with the material and the forming loads which are applied by the outer circumferential punch drive unit 23 and the blank holder drive unit 22 largely increase.
On the other hand, when the material pushed into the die 5 by the lowering of the outer circumferential punch 4 is too small, it is possible to prevent the forming load from increasing. However, the press forming proceeds in a state where a gap remains between the surface of the material 1 and the forming surface of the tool. In this case, the press forming is completed in a state where an unfilled portion which is not filled with the material remains between the press formed product and the tool, and forming failure may occur in the press formed product.
In addition, when the material is not sufficiently supplied into the position around the front end section of the punch 2 inside the tool, and as shown in
In order to review the method for performing press forming while appropriately managing the gap between the material 1 and the tool, the inventors examined by tests how a relationship between the gap between the material 1 and the tool, and the forming load applied to the tool was changed according to the progress of press forming.
That is, first, as shown in
At this time, the gap between the tool and the material 1 was examined in detail. As a result, as shown in
Subsequently, when the punch 2 and the counter punch 6 were lowered and the forming of the cylindrical protrusion 1A on the bottom wall portion 1a of the material 1 started, in the initial step of press forming, press forming proceeds in the state where a gap is present between the outer circumferential surface of the vertical wall portion 1b and the die 5.
Thereafter, as shown in
Next, tests in which a lowering speed of the outer circumferential punch 4 and a lowering speed of the punch 2 were changed relative to each other during press forming were performed.
For example, when the lowering speed of the outer circumferential punch 4 was faster than the lowering speed of the punch 2, a pushing amount of the vertical wall portion 1b by the outer circumferential punch 4 was excessively larger than an extension amount of the protrusion 1A by the punch 2. As a result, after the inside of the tool was filled with the material 1 of the vertical wall portion 1b, the pushing of the vertical wall portion 1b by the outer circumferential punch 4 was continuously performed, and an overload state occurred in which the material was further forcibly pushed into the filled portion of the vertical wall portion 1b. As a result, the forming load of the outer circumferential punch 4 exceeded the load capacity of the press forming device, and press forming was interrupted in a state where unfilled portions remained on the protrusion 1A.
On the other hand, the lowering speed of the outer circumferential punch 4 was slower than the lowering speed of the punch 2. Then, the forming load did not exceed the load capacity of the press forming device. However, forming was completed in a state where a gap remained between the material 1 and the tool, and forming failure occurred in the press formed product.
From the above-described results, in order to prevent occurrence of the unfilled portions between the material 1 and the tool and complete press forming in a state where the forming load was not excessive, it was ascertained that a gap filling situation of the material inside the tool which is managed to prevent the following matters was important. That is, in each of the vertical wall portion 1b and the protrusion 1A, if the pushing of the material into the die 5 by the outer circumferential punch 4 is continued after when the gap remained in the one of both during press forming and the gap of the other of both was filled with the formed product, the state of the filling portion became an overload state, and the forming load excessively increased. Since the forming load exceeded the load capacity of the press forming device and the forming cannot be continued, it was important to prevent the above-described matters.
In the present embodiment, in order to manage the gap between the formed product and the tool in multiple locations inside the tool during press forming, the sensor 7 for detecting the deformation amount of the tool was incorporated into the tool. In addition, with respect to the deformation of the tool according to filling of the material into the tool during press forming, the overload situation of the tool was detected using signals output from the sensor 7. In addition, a method of controlling the lowering speed of the tool such as the punch 2 to an appropriate value according to the overload situation was adopted. According to this method, the unfilled portions of the material 1 are not generated in the tool, and it is possible to complete forming in a state where the forming load is not excessive and does not exceed the load capacity of the press forming device and the operation of the press forming device is not stopped during forming.
A flowchart shown in
Subsequently to Step S102, the controller 10 determines whether or not a stroke Sps when a portion which is determined to a control object in advance among each portions of the tool divided into multiple portions moves reaches a predetermined final stroke Spse (Step S103).
In addition, when it is determined that the stroke Sps reaches the predetermined final stroke Spse (Yes in Step S103), the control ends, and when the stroke Sps does not reach the predetermined final stroke Spse (No in Step S103), the step proceeds to Step S104.
When the controller 10 determines that the sensor output εj from the sensor 7 does not exceed the sensor output determination value εJ (No in Step S104), the controller 10 continuously performs press forming without changing the lowering speed of the tool while sequentially reading the sensor outputs εj from the sensors 7 and returns the treatment to Step S102.
When a signal which exceeds the preset sensor output determination value εJ among the sensor outputs εj from the sensors 7 is input (Yes in Step S104), the number j of the sensor 7 is recorded as j0, and among the each portions of the tool divided into multiple portions, a lowering speed VPS of the portion which is determined to a control object in advance is decelerated to a value which is obtained by multiplying a value VPS0 set at an initial stage of forming by an arbitrary value a which is separately determined and is smaller than 1 (Step S105).
Thereafter, the controller 10 continuously performs the press forming while sequentially reading the sensor outputs εj from the sensors 7 (Step S106).
In addition, the controller 10 determines whether or not the stroke SPS of the portion which is determined to a control object in advance among the each portions of the tool divided into multiple portions reaches the predetermined final stroke SPSE (Step S107), and in a case where the stroke SPS reaches the predetermined final stroke SPSE (Yes in Step S107), the control ends.
When the output signal εj0 from the sensor 7 having the number j=j0 transmitting the signal exceeding the preset sensor output determination value εJ is smaller than a value obtained by multiplying the sensor output determination value εJ by an arbitrary value β which is smaller than 1 (Yes in Step S108) before the stroke SPS of the portion which is determined to a control object in advance among the each portions of the tool divided into multiple portions reaches the predetermined final stroke SPSE (No in Step S107), the lowering speed VPS of the portion which is determined to a control object in advance is corrected to the value VPS0 set at the initial stage of forming again, and the forming is continued. The above-described operations are repeated (No in Step S110) until the stroke SPS of the portion which is determined to a control object in advance among the each portions of the tool divided into multiple portions reaches the predetermined final stroke SPSE.
For example, in a case where the output value from the sensor 7 and the determination value corresponding to the predetermined overload state are compared with each other during the forming and the output value from the sensor 7 exceeds the determination value, the movement speed of one portion or the multiple portions among the each portions of the tool divided into multiple portions is corrected to a value in which the output value from the sensor 7 does not exceed the predetermined determination value.
According to the correction of the movement speed, the material viscously flows from the thickened portion of the material 1 in which the overload state is detected to other portions in which the state is not the overload state. In addition, according to proceeding of the flow of the material, the output value of the sensor 7 is gradually decreased. When the output value from the sensor 7 is lower than the predetermined determination value, the movement speed of each portion of the tool is adjusted such that the output value of the sensor 7 increases again.
A relationship between the filling situation of the material in the tool and the output signal from the sensor 7 may be separately obtained by test or the like according to the shape of the used tool.
For example, as the determination value which is compared with the output signal from the sensor 7 so as to determine whether or not the correction is added to the movement speed of the tool during forming, the output values of the sensors 7 in the forming process, when the press forming normally ends in a state where problems such as load excess in a general production do not occur are sequentially accumulated, and the maximum value of the accumulated data being used as the determination value may be considered. In addition, an another test with respect to press forming is performed, and a value at the time of overload which is obtained based on the relationship between the forming situation of the press formed product inside the tool and the output value of the sensor 7 can be used as the determination value.
Moreover, a numerical calculation such as a finite material method is performed, and a calculation value corresponding to the output of the sensor 7 which is assumed to be obtained, when the inside of the tool is filled with the material 1 can be used as the determination value.
In addition, before actual press forming is performed, preliminary processes including a calculation process, a measurement process, and a correction process described below are performed in advance, and the actual press forming may be performed according to the corrected prediction correspondence relationship (described below) obtained by the preliminary process.
In the calculation process, a prediction correspondence relationship between at least one of the driving force, the driving speed, and the driving timing applied to each portion of the tool, and the pressing force by which the overload state is not generated is obtained by a numerical calculation such as a finite material method.
In the measurement process, while the each portions of the tool are independently driven according to the prediction correspondence relationship obtained by the calculation process and the material 1 is press formed, the measurement correspondence relationship between the pressing force obtained by actually measuring the pressing forces applied to the each portions of the tool by the material 1 during the forming using the sensor 7 and at least one of the driving force, the driving speed, and the driving timing is obtained.
In the correction process, a difference between the prediction correspondence relationship obtained by the calculation process and the measurement correspondence relationship obtained by the measurement process is obtained, the prediction correspondence relationship is corrected, and a corrected prediction correspondence relationship is obtained.
The method for obtaining the determination value is exemplified as described above. However, determination values obtained by other methods may be used.
Hereinafter, with reference to a press forming method shown in
As shown in
That is, for example, while the lowering speed Vp of the punch 2 is constantly held or is increased, the lowering speed V0 of the outer circumferential punch 4 is slower than the lowering speed Vp. As a result, the material inflow of the material 1 from the vertical wall portion 1b to the protrusion 1A is promoted by the pulling of the punch 2, and it is possible to prevent the forming from being stopped due to the forming load exceeding the load capacity of the press forming device while decreasing the load applied to the outer circumferential punch 4 by alleviating the excessive filling of the material in the vertical wall portion 1b so as to prevent the increase in the forming load.
That is, in a case where the filling of the vertical wall portion 1b proceeds in a state where the protrusion 1A of the press formed product is unfilled during the forming, the signal indicating the overload exceeding the determination value is detected by only the sensor 7 of the vertical wall portion 1b. In this case, the bottom wall portion 1a is drawn downward by the pressing of the punch 2 to alleviate the filling of the vertical wall portion 1b while the lowering speed of the outer circumferential punch 4 is decreased so as to eliminate the overload state, and the material inflow into the bottom wall portion 1a is promoted. As a result, it is possible to advance the forming in a state where the vertical wall portion 1b is not overfilled with the material. Moreover, if the signal from the sensor 7 at the position corresponding to the vertical wall portion 1b is less than or equal to the determination value, it is possible to promote the filling of the material into the tool by increasing the lowering speed of the outer circumferential punch 4.
Thereafter, if the signal exceeding the determination value is output from the sensor 7 again, local filling of the material occurs in the vertical wall portion 1b, and it is detected that the state is overload state, the lowering speed of the outer circumferential punch 4 is decreased again so as to alleviate the overload state in the vertical wall portion 1b.
By repeating the control of the operation of the tool based on the output signal from the sensor 7, as shown in
On the other hand, as shown in
In a case where the vertical wall portion 1b is filled with material before the protrusion 1A of the material 1 is press formed in predetermined dimensions, the state becomes the overload state, and the load increases, the relative lowering speed between the outer circumferential punch 4 and the punch 2 is appropriately changed based on the output signal from the sensor 7 according to the deformation of the tool. As a result, occurrence of the unfilled portion in the vertical wall portion 1b is prevented, a situation in which the state becomes the overload state and the forming load exceeds the load capacity of the press forming device is prevented, and a product having a predetermined shape is obtained.
In addition, in the embodiment, the relative lowering speed between the outer circumferential punch 4 and the punch 2 is appropriately changed. However, the control element is not limited to the lowering speed, and at least one of the driving force, the driving speed, and the driving timing applied to each portion of the tool can be used. That is, a relative difference between the driving force of the outer circumferential punch 4 and the driving force of the punch 2 may be provided, and a relative difference between the driving timing of the outer circumferential punch 4 and the driving timing of the punch 2 may be provided. In addition, with respect to combination of three elements of the driving force, the driving speed, and the driving timing, the relative difference between the outer circumferential punch 4 and the punch 2 may be provided.
As described above, the gist of the present embodiment is as follows.
The press forming method according to the present embodiment includes: the first process of obtaining the pressing force applied to the die 5 of the tool by the material 1 during press forming using the sensor 7 while independently driving the punch 2, the blank holder 3, the outer circumferential punch 4, and the counter punch 6 which are the tool divided into multiple portions and press forming the material 1; and the second process of adjusting at least one of the applied driving force, the applied driving speed, and the applied driving timing for each punch 2 of the tool and each outer circumferential punch 4 of the tool to cause the press processing portion of the material 1 in which the state approaching an overload state is detected based on the pressing force to flow to other press processing portions of the material 1.
In the first process, the pressing force is obtained based on the deformation amount (strain amount) of the die 5 of the tool generated according to the flow of the material 1 during press forming.
In the second process, whether or not the state has approached the overload state is determined by whether or not the pressing force exceeds the predetermined threshold value (determination value).
In addition, the press forming is drawing for forming the material 1 into a cylindrical member having an axis line. Moreover, for example, as shown in
The present invention is not limited to the aspect in which the pressing force is detected by only the sensor 7 provided in the die 5. An aspect in which the sensor 7 is provided in at least one of the punch 2, the blank holder 3, the outer circumferential punch 4, and the counter punch 6 may be adopted. For example, in an aspect shown in
Moreover, preferably, the detection unit of the sensor 7 is positioned at a position of a depth of 5 mm to 50 mm from the forming surface of each portion (for example, the die 5, the punch 2, or the like) of the tool on which the sensor 7 is provided. When the detection unit is positioned at the position of the depth of 50 mm or more from the forming surface, since detection sensitivity of the strain amount is rapidly decreased, it is not preferable. On the other hand, when the detection unit is positioned at the position of the depth of 5 mm or less from the forming surface, the sensitivity of the sensor 7 is excessive, and there is a concern that the strain amount cannot be correctly measured.
Hereinafter, a second embodiment of the present invention will be described. In the second embodiment, differences between the first embodiment and the second embodiment are mainly described, and descriptions with respect to the portions which are the same as those of the first embodiment are omitted.
In the present embodiment, as shown in
As described above, the vertical wall portion 1b or the protrusion 1A may not be uniformly filled with the material. For example, as shown in
Accordingly, since the multiple sensors 7 are disposed, it is possible to control the lowering speed of each of the outer circumferential punch 4 and the punch 2 so as to detect local filling to prevent a partial overload state. In this case, it is possible to more accurately prevent the load increase due to occurrence of the local overload state and decrease the forming load, and it is possible to perform press forming without exceeding the allowable load of the press forming device and allowing the unfilled portions to remain.
For example, as shown in
Hereinbefore, embodiments of the present invention are described with reference to the drawings. However, the present invention is not limited to only the disclosures of the embodiment.
For example, the forming method which is the object of each embodiment is not necessarily limited to only the method which uses the cup-shaped intermediate material shown in
In addition, in the forming method which is the object of each embodiment, the tool which is divided into multiple portions in which relative speed ratios are controlled is not necessarily limited to only the above-described punch side. The present invention is applied to a dice side (not shown) divided into multiple portions, and can be applied to relative speed controls between the multiple dices and the punch. In addition, each of the dice and the punch is divided (not shown) into multiple portions, and relative speed controls may be performed on each of the dice and the punch.
The shape of the material 1 or the shape of the tool shown in each embodiment is exemplified so as to describe the present invention, and other shapes thereof may be adopted.
In addition, in the above-described embodiments, the strain sensor is used as a unit for detecting the pressing force which is applied to each portion of the tool by the workpiece material. However, ultrasonic waves or magnetic change being used as other methods may be considered.
According to the forming method shown in
First, for comparison, simple press forming was performed. That is, after press forming proceeded to the state of
Next, press forming was performed in a state where the above-described first embodiment was applied to forming. That is, after forming proceeded to the state of
Here, as the determination value, in the forming process, when press forming normally ended without problems such as load excess, the maximum value of the output values from the sensor 7 which were accumulated in a general production was used. In addition, when the strain signal reached the determination value, the lowering speed of the outer circumferential punch 4 was decreased from 1.4 times the lowering speed of the punch 2 at the initial stage to 1.0 time the lowering speed of the punch 2.
Thereafter, when the value of the strain signal from the sensor 7 gradually decreased and reached 0.9 times the determination value, the lowering speed of the outer circumferential punch 4 was increased to 1.4 times the lowering speed of the punch 2 at the initial stage by the instruction of the controller 10. As a result, press forming could be completed in a state where the press forming load did not exceed the allowable limit of the forming device.
First, for comparison, simple press forming was performed. That is, according to the press forming method shown in
Next, after the embodiment shown in
Here, as the determination value, an output value at the time of an overload was used, which was separately obtained by a press forming test and was obtained from a relationship between the forming situation of the press formed product inside the tool and the output value of the sensor. In addition, when the strain signal reached the determination value, the lowering speed of the outer circumferential punch 4 was decreased from 1.2 times the lowering speed of the punch 2 at the initial stage to 0.9 times the lowering speed of the punch 2.
Thereafter, when the value of the strain signal from the sensor 7 gradually decreased and reached 0.8 times the determination value, the lowering speed of the outer circumferential punch 4 was increased to 1.2 times the lowering speed of the punch 2 at the initial stage by the instruction of the controller 10. As a result, press forming could be completed in a state where the press forming load did not exceed the allowable limit of the forming device.
According to the present invention, it is possible to provide a press forming method and a tool for press forming capable of preventing a load applied to a tool from exceeding a load limit of a press forming device so as to prevent forming not being possible, and of stably drawing a product in which forming failure associated with the unfilling the tool with a material do not occur.
1: WORKPIECE MATERIAL
2: PUNCH
3: BLANK HOLDER
4: OUTER CIRCUMFERENTIAL PUNCH
5: DIE
6: COUNTER PUNCH
7: STRAIN SENSOR, SENSOR
10: CONTROLLER
11: STORAGE UNIT
21: PUNCH DRIVE UNIT
22: BLANK HOLDER DRIVE UNIT
23: OUTER CIRCUMFERENTIAL PUNCH DRIVE UNIT
24: COUNTER PUNCH DRIVE UNIT
Number | Date | Country | Kind |
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2014-103735 | May 2014 | JP | national |
This application is a Divisional of copending application Ser. No. 15/311,883, filed on Nov. 17, 2016, which is the National Phase under 35 U.S.C. § 371 of International Application No. PCT/JP2015/063750, filed on May 13, 2015, which claims the benefit under 35 U.S.C. § 119(a) to Patent Application No. 2014-103735, filed in Japan on May 19, 2014, all of which are hereby expressly incorporated by reference in their entirety into the present application.
Number | Date | Country | |
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Parent | 15311883 | Nov 2016 | US |
Child | 16457513 | US |