• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a method for producing a workpiece (6) having at least two bends (Bi) by bending a sheet metal blank (2), comprising the following steps: a) providing (10) a set ({S}) of bending sequences ( BSm) and storing (11) the sentence ({S}) as a selection set ({AS}); b) expanding (12) the set ({S}) by new bending sequences (BSm); c) calculating (13) a score (SCm) for each bend sequence (BSm) of the set; d) selecting (13) the bend sequences (BSm) with the N best scores (SCm) among all the bend sequences (BSm) of the set ({S}) and storing the selected bend sequences (BSm) as a selection set ({AS}); and e) bending (15) the sheet metal blank (2) with one of the bending sequences (BSm) of the selection set ({AS}) in which all the bends (Bi) are present. The invention further relates to a computer program product and a folding machine for implementing the said method.
    公开号:AT517966A4
    申请号:T50117/2016
    申请日:2016-02-22
    公开日:2017-06-15
    发明作者:Ing Henning Scharsach Dipl;Mag Markus Tschanter Ing
    申请人:Ing Henning Scharsach Dipl;Mag Markus Tschanter Ing;
    IPC主号:
    专利说明:

    The present invention relates to a method for producing a workpiece with at least two bends by bending a sheet metal blank, wherein at least one of the bends can be produced in two variants. The invention further relates to a computer program product and a folding machine for implementing the said method.
    For bending sheet metal on swaging or bending machines, an order of the bends to be carried out on the sheet metal blank is first of all determined in order to subsequently produce the workpiece as efficiently as possible, saving time and resources. Each bend to be made can usually be made in different variants, e.g. by bending up or down, turning or turning the blank, by manual or mechanical bending, etc. Different variants usually result in different lengths of production times during production, whereby a certain sequence of bends in each case a particular bending variant, a so-called "bending sequence", each requiring a certain production time.
    The combination of all possible sequences of bends and their different bending variants, however, results in an enormously large number of possible bending sequences, namely (number of bends)! * (Number of variants) Λ (number of bends). For example, for ten bends, each of which can be produced in four variants, there are already 10! * 410 * 4 trillion possible bending sequences.
    Finding the optimal bending sequence ("bending strategy") for producing a workpiece with a predetermined sequence of bends with certain bending angles at certain mutual distances ("profile geometry"), u.zw. optimal in terms of minimum manufacturing time and minimum number of manipulation steps on the blank, is therefore a non-trivial problem given the enormous number of possible bending sequences. Even finding a merely sub-optimal bending sequence requires years of experience in practice to arrive at a useful bending sequence within a reasonable time.
    Computer-assisted methods have therefore already been developed which "try" a large number of possible bending sequences, but these methods either lead to significantly poorer solutions than experienced specialists or require unreasonably high computation time or computing power, since a bending sequence must always be calculated for each bending variant Whether collisions during bending of the sheet metal blank would occur due to already produced bends, the computation time is extended correspondingly with each further bending variant added to a bending sequence.
    The invention has as its object to overcome the disadvantages of the prior art and to provide a method which provides high-quality results in a short computing time, i. Bending sequences with short production times to make the workpiece quickly and efficiently.
    This object is achieved according to a first aspect of the invention with a method of the type mentioned in the introduction, comprising the following steps: a) providing a set of bending sequences comprising one bending variant, all bending variants resulting from the totality of the bends in all their variants and storing the sentence as a selection set; b) expanding the set by new bending sequences, each of which is supplemented by a bending sequence of the selection set by at least one further respective possible bending variant, over a predetermined period or until a predetermined number of new bending sequences is reached; c) calculating a score for each bend sequence of the set in each case depending on evaluations of the bend variants in this bend sequence and the calculation time used for the calculation of this bend sequence; d) selecting the bend sequences with the N best scores among all the bend sequences of the set and storing the selected bend sequences as a selection set; e) if a predetermined calculation time has not yet been reached, repeating steps b) to d), otherwise bending the sheet metal blank with one of the bending sequences of the selection set in which all the bends are present.
    According to the method, an algorithm is used in step b), by means of which new bending sequences are determined. According to the invention, after a predetermined period of time, e.g. periodically, a "snapshot" of the already determined, possibly not yet all bends-containing, i.e. "unfinished", bend sequences created to estimate which of these bend sequences could result in further completion at low production times; These are selected and used as a starting point for the further bending sequences to be determined.
    The method thus effects a periodically significant "thinning out" of the plurality of possible bend sequences, the available computational power, and computation time to complete each of the potentially "best" bend sequences, e.g. those with the expected lowest production times and costs. In accordance with the invention, evaluations of the bending variants in these bending sequences and the calculation time each used for the calculation of these bending sequences are used for this purpose. The invention is based on the recognition that the computing time consumed for a (unfinished) bending sequence is a "negative quality measure", i.e. a "bad" bending sequence with e.g. indicates a particularly high collision potential.
    Preferably, a bend is defined by a bending angle, a bending distance from an edge of the sheet metal blank and optionally an angle to an edge of the sheet metal blank. This allows a particularly simple collision determination, whereby the computing time used in this regard is minimized.
    Further preferably, a variant of a bend is defined by at least one of the bending parameter bending direction, Blechroh-ling-turning direction, plate blank rotation direction and tool change. The bending and turning direction parameters are particularly advantageous for sheet metal blanks coated on one side, as the coating of the sheet can be spared by appropriate choice. The direction of rotation indicates whether the sheet metal blank must be re-clamped for bending. The parameter tool change can indicate whether another bending tool, another bending machine or a manual bending should be used, e.g. to achieve higher or more accurate bending angles.
    In a further advantageous embodiment of the invention, in step b) generating a bend sequence comprises applying a set of rules to the respective bend sequence of the selection set and to all other possible bend variants to determine which of those bend sequences is added to the set. This solution provides a way of determining the bending sequences, e.g. structurally using collision rules. Alternatively, an algorithm can be used by means of which bending sequences are created by random selection in order to determine bending sequences more quickly. Both algorithms can also be used in parallel or sequentially.
    In the aforementioned embodiment, each rule preferably provides an evaluation of a bending pattern identified in the workpiece to be produced, of the variants contained in the bending sequence and / or of bending collisions occurring. For example, an identified bending pattern may be a fold at one end of the workpiece, which experience has shown to produce the best at the beginning of a bend sequence, whereby the bends of such a pattern receive a good score. The evaluation of the variants refers to whether the workpiece can be manufactured quickly with this bending sequence, e.g. with a few blank conversion steps or manual production steps.
    The evaluations mentioned in step c) are preferably determined with regard to a bending pattern identified in the workpiece to be produced or with regard to the variants contained in the bending sequence. As a result, in the aforementioned "snapshot" selection, both bending patterns and estimated production speeds can be taken into account.
    Further preferably, said predetermined period of time is 0.1 to 3 seconds, more preferably 0.2 to 2 seconds, whereby the "snapshot" selection of the most promising bend sequences to be "continued" - e.g. with an available computing time of 6 to 20 seconds - 1 to 200 times can be performed. This results in a good balance between recalculations of bend sequences by the algorithm of step b) and reselection of exit bend sequences. However, said predetermined period of time may also be dependent on the number of bends and variants.
    In a further preferred embodiment of the invention, said predetermined (total) computing time is 6 to 20 seconds, more preferably 10 to 15 seconds. As a result, bending sequences can be determined with short production times, without resulting in the user of the process an excessive waiting time between input of the bending data and starting the bending of the sheet metal blank.
    According to a second aspect of the invention there is provided a computer program product for controlling a programmable pivoting bending machine embodied on a machine readable medium and adapted for when the pivoting bending machine is programmed to execute said method.
    According to a third aspect of the invention there is provided a folding machine with program control programmed to carry out said method.
    With regard to the advantages of the computer program product and the folding machine according to the second or third aspect of the invention, reference is made to the advantages of the method according to the first aspect of the invention.
    The invention will be explained in more detail with reference to embodiments illustrated in the accompanying drawings. In the drawings: Figures la and lb a folding machine for performing the method according to the invention in sections in two different operating states; Figures 2a - 2c show examples of workpieces to be produced by the method of the invention;
    3 shows an exemplary definition of a profile geometry for a workpiece with a plurality of bends;
    4 shows an exemplary definition of the bending variants of a bending of the profile geometry of FIG. 3;
    5 shows a flowchart of the method according to the invention;
    FIG. 6 shows example bending sequences in the method of FIG. 5; FIG.
    FIG. 7 illustrates the creation of the bend sequences of FIG. 6 in accordance with a set of rules; FIG. and
    FIG. 8 provides bending sequences at various times in the course of the method of FIG. 5 in successive tree representations.
    Fig. La shows a detail of a folding machine 1, in which a sheet metal blank 2 is clamped between a top beam 3 and a lower beam 4. It can be seen from the sequence of FIGS. 1a and 1b that the sheet metal blank 2 is formed by moving a bending cheek 5 into a semifinished product or workpiece 6 with a bend Bi. Bending may be done by swivel bending as shown or alternatively by other forming methods known in the art, such as swaging.
    Figures 2a, 2b and 2c show some examples of workpieces 6 made with a plurality of different bends B1 # B2, ..., generally Bi, and thereby have a variety of shapes. The bends Bi of the workpieces 6 are bent in each case in a specific order, which, however, the finished workpiece can not be viewed. The entirety of all the bends Bi of the workpiece 6 will be referred to as {b} hereinafter.
    Fig. 3 shows an example of a definition 8 of the bends {B} ("profile geometry") of the workpiece 6. Each bending Bi is eg by a bending distance a from an edge 7 'of the sheet metal blank 2 or a stop 7 "of the folding machine 1 (see Fig. Lb, 2a) defines a bending angle α and (optionally) an angle ß to the edge 7 'or the stopper 7 ".
    According to Fig. 4, in the manufacture of the workpiece 6, each bend Bi can be made in a different way, i. in a multiplicity of variants Vi, V2,..., generally Vj. Each variant Vj of the bend Bi can be bent by various bending parameters such as bending direction "U / D" (1 = up, 0 = down), sheet metal blanking direction "FLIP" (1 = turning, 0 = leaving), "RED" ( 1 = turning, 0 = leaving), tool change "H / M" (1 = dog, 0 = machine, or tool number) etc. are defined. The totality of the variants Vj of a bend Β ± is referred to below as {v} Bi, a bend Bi in the variant Vj as a "bend variant" BVi, j, and the totality of all such bend variants as {bv}.
    A particular order of bends Bi in a respective bending variant BVi, j, with which the workpiece 6 can be made, is referred to as a "complete" or "complete" bending sequence; a part of it as "unfinished" or "incomplete" bending sequence BS.
    The multiplicity of bends Bi and their variants Vj result in an enormous number of potential bending sequences BSi, BS2,..., Generally BSm. However, some of these potential bending sequences BSm are not feasible due to collisions or would require a very long production time and / or very high production costs due to frequent tool changes, Umspannschritte the sheet blank 2, manual bending steps, etc.
    Determining the most suitable, i. The fastest or most resource-conserving, complete bending sequence (s) will now be described with reference to FIGS. 6 to 8, wherein reference is made to the flowchart of FIG. 5.
    Fig. 5 shows at the top and Fig. 6 at the left the initial step a) of providing a first (start) set {S} of (initially incomplete) bending sequences BSm, which consists of all basically possible variants j all as the first bend of the sequence (b) which is to be used (ie all bending variants {BV}, composed (10).) This set {S} is stored as the first selection set {AS} (11).
    In the next step b), the selection set {AS} is extended (12) by a multiplicity of bending sequences BSm + n to be determined in this step b), the index n designating the nth new bending sequence generated in step b). Each new bending sequence BSm + n consists of one of the previously determined (incomplete) bending sequences BSm, supplemented or further completed by one (or more) next bend (s) Bi to be made in a respective variant Vj, i. one (or more) further bending variant (s) BVi, J (together.
    Fig. 7 shows a possible algorithm for determining such a new bending sequence BSm + n. In order to further develop an (unfinished) bending sequence BSm present in the set {S}, it is first determined which bends Bi are not yet present in the bending sequence BSm. Subsequently, all bending variants BVi, j are determined which are still possible for these bends Bi. A set {rule} of rules rulei, rule2, ..., generally ru-lek, is applied to every combination resulting from the bending sequence BSm and all possible bending variants BVi (j) for its further completion ("extension"), to generate new bending sequences BSm + n = BSm + BVi, j.
    The rules rulek can be divided into several classes, three of which are shown here by way of example. Thus, for example, the rule rulei could provide a rating Evali with respect to a bending pattern identified in the workpiece 6 to be produced. Thus, e.g. It can be seen in the pattern of FIG. 2b that the two fold bends Bi, Bv can be generated particularly easily at the beginning of the method, which is why they would then receive a good evaluation Evali at the corresponding position in a bending sequence. Such patterns to be recognized are based on expert rules; e.g. also concave courses such as B2-B3-B4-B5-B6 could be detected and evaluated Evali.
    Other rules rule 2 provide e.g. an evaluation Eval2 with regard to the variants BVu already contained in the (unfinished) bending sequence BSm, for which, for example, a frequent tool change or a frequent turning or turning of the sheet metal blank would be rated as poor. Again other rules rule3 provide e.g. an evaluation Eval3 with respect to an expected bending collision, whereby unfinished bending sequences BSm + n can be eliminated.
    It is understood that not all rules must be applied rulek, but for example, the application of the rules of the sentence {rule} on the occurrence of certain criteria can also be terminated early, resulting in different calculation times tr for the generation of different bending sequences BSm + n can.
    Those new bending sequences BSm + n with the best scores-or even all manufacturable-are added to the set {S} in step b), thereby expanding it (12). Instead of only one bending variant BVi, j, several bending variants can also be added one after the other to an existing bending sequence BSm, for example using the algorithm described above. To make this possible, newly generated bending sequences Bm + n can replace or be added to the underlying bending sequences BSm in the selection set {AS}.
    When bending variants BVi, j are added to the bending sequences BSm of the set {S} in step b), successively longer bending sequences BSm + n are thus produced until all bends {B} are present in a bending sequence BSm + n. An exemplary bending sequence BSm may e.g. be given by the order BSm = BV3,2 -> BVi, i -> BV4,3 -► ....
    The step b) of extending (12) of the set {S} is carried out until either a predetermined period of time At has elapsed or a predetermined number M of new bending sequences BSm + n has been generated. The time period At may be e.g. in the range of 0.1 to 3 seconds, in particular 0.2 to 2 seconds. The predetermined number M of new bending sequences BSm + n can e.g. also be a certain percentage of all possible bending sequences BSm.
    After - or even during - step (es) b), a score SCm for each bending sequence BSm of the (now extended) sentence {S} is calculated in a step c) (13).
    On the one hand, the score SCm is made up of the ("used-up") computing time tr that was previously used for the calculation of this bending sequence BSm, which is due to the different complexity of the rule set {rule} for the different bending sequences BSm and the respectively differently available bending variants BVi j is individually different for each bending sequence BSm.
    On the other hand, the score SCm is composed of one or more of the evaluations Evali, Eval2, Eval3, generally Evalp, the bending variants BVi, j in this bending sequence BSm. The assessments can be the same as in step b) and also come from the same calculation process or alternatively be separate evaluations. It can therefore be seen that steps b) and c) could optionally also be carried out simultaneously.
    By means of an optional function f, e.g. Thus, for example, SCm = f ({Evalp (BSm)}, tr (BSm)) also calculates a weighting of its arguments.
    The calculation time tr of a bending sequence BSm is made up of the individual calculation times tr, i, j of the bending variants BVifj contained in the bending sequence BSm according to tr = Σ.
    In a subsequent step d), the bending sequences BSm are selected from the set {S} with the N best scores SCm (N = 1, 2, ...) and stored as a new selection set {AS} (14), i. the old selection set {AS} is overwritten. As a result, "bad", less promising bending sequences BSm are eliminated from the selection set {AS}, and consequently these eliminated bending sequences BSm can no longer serve as the basis for new bending sequences BSm + n since they are no longer present in the selection set {AS}.
    After the selection and storage step d), it is checked in a step e) whether a given (total) computing time tges has been reached or not (15). If not (branch "N"), it returns to step b) to repeat steps b) -d) until re-test 15. However, if test 15 indicates that the predetermined calculation time tges has been reached (branch " Y "), the loop b) - d) is left and passed on to sub-step 16 of step e), in which now those bending sequences BSm of the selection set {AS} are determined which contain all the bends {b}.
    The bending sequences BSm determined in partial step 16 can optionally be further evaluated with regard to their production speed, e.g. by means of said evaluation Eval2 with respect to the variants Vj contained in the bending sequence BSm in order to further select from these bending sequences BSm (17). Alternatively, the selection step 17 can be omitted and a random one of these complete bending sequences BSm selected, or the user manually selects one of the bending sequences BSm obtained at the exit of step 16 in step 17.
    Finally, in the last partial step 18 of step e), the sheet metal blank 2 is bent by the bending machine 1 according to the selected complete bending sequence BSm.
    It can be seen that the predetermined period of time At, over which the set {s} is expanded by new bending sequences BSm + n in step b), defines those points in time at which the set {S} is respectively determined by means of the steps c) and d). - As in a "snapshot" - is re-evaluated in order to determine therefrom the selection set {AS} of in the next loop iteration b) - d) "to be continued" bending sequences BSm.
    FIG. 8 shows this in detail on the basis of successive "snapshots" of the set {S} starting from the start (selection) set at a time 0 and after approximately lAt, 2At and 3At, ie after one, two or three passes of the Loop b) - d) The bending sequences of the sentence {S} are each represented as branches of a decision tree whose nodes each represent a bending variant BVi; j.
    The respective bending sequences of the set {S} selected in step d) for the "continue building", ie the selection set {AS} for the step b) of the next pass are illustrated with thick solid lines, the set of newly added bending sequences Bm + n with dotted lines and other bending sequences Bm of the set {S} with thin solid lines.
    The predetermined computing time tges, after which the loop b) - d) is interrupted and the bending e) is carried out, is preferably 6 to 20 seconds, more preferably 10 to 15 seconds, and can also be dynamic depending on the number or production rate of the complete Bend sequences BSm be adapted.
    The invention is therefore not limited to the illustrated embodiments, but includes all variants, modifications and combinations thereof that fall within the scope of the appended claims.
    权利要求:
    Claims (10)
    [1]
    Claims:
    1. A method for producing a workpiece (6) with at least two bends (Bi) by bending a sheet metal blank (2), wherein at least one of the bends (Bi) in two variants (Vj) can be produced, comprising the following steps: a) Provide (10) of a set ({S}) of bending sequences (BSm) each comprising a bending variant (BVi; j), all bending variants (BVi, j) resulting from the totality of the bends (Bi) in all their variants (Vj) , and storing (11) the sentence ({S}) as a selection set ({AS}); b) expanding (12) of the set ({s}) by new bending sequences (BSm), each consisting of a bending sequence (BSm) of the selection set ({AS}) supplemented by at least one further possible bending variant (BVi (j)) c) calculating (13) a score (SCm) for each bend sequence (BSm) of the set ({S}) in each case depending on valuations (A) or until a predefined number of new bend sequences (BSm) has been reached; Evalp) of the bending variants (BVi, j) in this bending sequence (BSm) and the calculation time (tr) consumed for the calculation of this bending sequence (BSm); d) selecting (14) the bend sequences (BSm) with the N best scores (SCm) among all the bend sequences (BSm) of the set ({S}) and storing the selected bend sequences (BSm) as a selection set ({AS}); e) if a predetermined computing time (tgeE) has not yet been reached, repeating steps b) to d), otherwise bending (18) the sheet metal blank (2) with one of the bending sequences (BSm) of the selection set ({AS}) in which all bends (Bi) are present.
    [2]
    2. The method according to claim 1, characterized in that a bend (B ±) by a bending angle (a), a bending distance (a) of an edge (V) of the sheet metal blank (2) and optionally an angle (ß) to an edge (V) of the sheet metal blank (2) is defined.
    [3]
    3. The method according to claim 1 or 2, characterized in that a variant (Vj) of a bend (Bi) by at least one of the bending parameter bending direction (U / D), sheet blank rolling direction (FLIP), sheet blank rotational direction (ROT) , Tool change (H / M) is defined.
    [4]
    4. The method according to any one of claims 1 to 3, characterized in that in step b) generating a bending sequence (BSm) applying a set of rules ({rule}) to the respective bending sequence (BSm) of the selection set ({AS} ) and all other possible bend variants (BV / i; j) to determine which of these bend sequences (BSm) will be added to the set.
    [5]
    5. The method according to claim 4, characterized in that each rule an evaluation (Evalp) with respect to a workpiece to be produced in the (6) identified bending pattern, with respect to the variants contained in the bending sequence (BSm) (Vj) and / or with respect to bending collisions occurring supplies.
    [6]
    6. The method according to any one of claims 1 to 5, characterized in that said in step c) evaluations (Evalp) with respect to one in the workpiece to be produced (6) i-dentified bending pattern or in terms of the bending sequence (BSm) variants (Vj ) be determined.
    [7]
    7. The method according to any one of claims 1 to 5, characterized in that said predetermined period of time (At) is 0.1 to 3 seconds, preferably 0.2 to 2 seconds.
    [8]
    8. The method according to any one of claims 1 to 5, characterized in that said predetermined computing time (tges) is 6 to 20 seconds, preferably 10 to 15 seconds.
    [9]
    A computer program product for controlling a programmable pivoting bending machine (1) embodied on a machine readable medium and adapted for when the pivoting bending machine is programmed to carry out the method of any one of claims 1 to 8.
    [10]
    A folding machine with program control programmed to carry out the method of any one of claims 1 to 8.
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    同族专利:
    公开号 | 公开日
    AT517966B1|2017-06-15|
    EP3211499B1|2018-09-26|
    EP3211499A2|2017-08-30|
    EP3211499A3|2018-02-28|
    引用文献:
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    DE69838336T2|1997-09-11|2008-01-03|Amada Co., Ltd., Isehara|DEVICE AND METHOD FOR MULTI-PIECE DESIGN PLANNING FOR METAL PLATE BENDING PROCESSES|
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    JP2003326319A|2002-05-14|2003-11-18|Denso Corp|Method for simulating three-dimensional bending work of base stock|CN109248940A|2018-08-27|2019-01-22|宁波欣达(集团)有限公司|The bending method of automatic integrated system and application automatic integrated system|JPH06142768A|1992-11-05|1994-05-24|Komatsu Ltd|Method for deciding bending order for metallic sheet|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50117/2016A|AT517966B1|2016-02-22|2016-02-22|Method, computer program product and bending machine for bending sheet metal|ATA50117/2016A| AT517966B1|2016-02-22|2016-02-22|Method, computer program product and bending machine for bending sheet metal|
    EP17156876.9A| EP3211499B1|2016-02-22|2017-02-20|Method, computer program product and bending machine for bending metal sheets|
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