EP3291927A2

EP3291927A2 - Method for the simplified creation of a component, component obtained by such a production method and method for selecting between a simplified or non-simplified production method

Info

Publication number: EP3291927A2
Application number: EP16726356.5A
Authority: EP
Inventors: Pierre Colin; Yves BONNEMAYRE
Original assignee: PSA Automobiles SA
Current assignee: PSA Automobiles SA
Priority date: 2015-05-05
Filing date: 2016-05-03
Publication date: 2018-03-14
Also published as: RU2732552C2; RU2017142086A3; BR112017023329B1; WO2016177962A2; RU2017142086A; BR112017023329A2; WO2016177962A3

Abstract

The invention relates to a simplified method for producing a component from a sheet metal blank, involving several steps, including a single forming step which consists in using a single press-forming press that has just one direction of pressing to form a rough form of the component, characterized in that the sheet metal blank is held in position during the forming step using one or more indexing hole(s) collaborating with one or more peg(s) of the press-forming press. The invention also relates to a method for selecting between the simplified method for creating a component and a non-simplified method of creating said component.

Description

SIMPLIFIED REALIZATION METHOD OF A PIECE, PIECE OBTAINED BY SUCH AN IMPLEMENTATION METHOD AND SELECTION METHOD BETWEEN A SIMPLIFIED OR UNFREE SIMPLIFIED REALIZATION METHOD

The present invention relates to a method of simplified production of a workpiece from a sheet blank, which comprises several steps, including a single forming step which consists of using a single stamping tool, presenting only one direction of movement of the press, to form a blank of the part. The present invention also relates to a method of selection between the method of simplified production of a part and a method of non-simplified production of said part, using heavy industrial means.

Usually, on a stamping line, as described in the document FR2966137, a method of producing a part comprises several forming steps, each forming step using a stamping tool that makes it possible to form a part. Such a stamping tool comprises a main press and punches which move in several directions. The movement of these punches is actuated by the descent of the main press and by the presence of cams of angles. Such stamping tools, which use heavy industrial means, are very complex to implement and require very large investments. However, in the case of manufacturing small series parts, such investments significantly increase the price of these parts.

FIG. 1 shows the evolution between the cost of a stamping tool Ct and the labor time T required for an operator to be able to perform manual finishing operations on the part, once the part formed by the stamping tool. By manual finishing operations is understood operations of dropping parts of the part that would have required a bevel gear in the stamping tool for such a fall is done automatically during the forming step. Is also understood by manual finishing operations, folding operations that are performed outside the axis movement of the press and volume retrofit operations. The curve F represents the variation between the increase in the cost of stamping tools and the reduction in the time spent manually finishing the workpiece. And also represented three areas:

The first zone Z1 represents a zone in which a good balance is achieved between the time of finishing operations T which remains below a first finishing time threshold T1 and the cost of the stamping tool Ct which remains below a first cost threshold of a stamping tool Ct1;

The second zone Z2 represents an area where either:

The gain on the cost of a stamping tool Ct with respect to the increase in the finishing time T which is beyond the first threshold of finishing time T1, while remaining below a second threshold of T2 finishing time, or

The saving of the finishing time T with respect to the extra cost of the stamping tool Ct which is above the first cost threshold of a stamping tool Ct1, while remaining below a second threshold of The cost of a stamping tool Ct2 is not enough to know for sure whether the gain is of sufficient interest.

The third zone Z3 represents an area where either:

The gain on the cost of a stamping tool Ct compared to the increase in the finishing time T which is above the second threshold of finishing time T2, or

The saving of the finishing time T with respect to the extra cost of the drawing tool Ct which is above the second cost threshold of a stamping tool Ct2, is insufficient compared to the expected gain. An industrial solution that is in zone Z3 is to be avoided.

In the automobile world, we can consider, to define the three zones, that:

The first finishing time T1 is of the order of 4 minutes; The second finishing time T2 is of the order of 5 minutes;

• the first cost of a stamping tool Ct1 is of the order of 5000 Euros; and

• the second cost of a stamping tool Ct2 is of the order of 15000 Euros. Of course, such values can vary according to various parameters, but the purpose of such a graph is above all to show that the change between the cost of a stamping tool Ct is inversely proportional to the finishing time T and that it is interesting to set limits so as not to excessively lengthen the labor time or production cost of industrial stamping tools. All this allows to have a fair investment both human and financial for the realization of a piece. But the finishing time is not a sufficient criterion to know for sure, if the realization of a piece justifies the establishment of heavy industrial means or if a simplified method of implementation, using a single-action press, but with more manual finishing operations, is preferable.

The object of the invention is to have a simplified method of producing a part which has a low investment cost and a process development time which is shortened. The object of the invention is also to have a selection process between a simplified method for producing a part and a non-simplified production method that requires the establishment of heavy industrial means. Such a selection process must make it possible, according to objective criteria, to justify such a choice. To this end, there is provided, according to the invention, a simplified method for producing a part for a vehicle, such as a motor vehicle, from a sheet blank, which comprises several steps, including a step single forming method which consists in using a single stamping press having only one direction of stamping, to form a blank of the part. According to the invention, the sheet blank is held in position during the forming step by means of one or more indexing hole (s) which collaborates (s) with one or more pion (s) of the stamping press. The indexing hole (s) is (are) formed during a preparation step that precedes said forming step. According to a first feature of the invention, the preparation step comprises a succession of cutting and punching steps of the sheet blank.

According to a second characteristic of the invention, the indexing hole (s) is (are) formed in a portion of the sheet blank that is intended to be removed during a step of fretwork which follows the step of forming.

According to a preferred embodiment of the invention, the fretwork stage is performed by means of a laser-type cutting device with a three-dimensional definition.

According to a third characteristic of the invention, the method of simplified production of a part comprises a final finishing step comprising at least one manual shaping operation of the blank of the workpiece, said shaping operation having at least one less a deformation operation of a portion of the blank of the part being in a direction of deformation different from the drawing direction of the stamping press. The present invention also relates to a part intended to form a part of a vehicle, such as a motor vehicle, the part being made by the simplified embodiment comprising at least one of the preceding features. The present invention finally relates to a method of selection between the simplified method of producing a part comprising at least one of the preceding characteristics and a method of non-simplified production of said part. According to the invention, the selection process is such that it comprises at least two selection criteria. Each selection criterion is broken down into three previously established ranges of values, each range corresponding, respectively, to one of three levels of selections. For each selection criterion, a value of a technical characteristic of the part is determined, said value then being listed in one of the corresponding value ranges of each selection criterion, so that:

When the selection level of all the selection criteria of the part corresponds to the first level of selection, it is chosen to produce the part by the simplified production method; or

When the selection level of at least one of the selection criteria corresponds to the third selection level, it is chosen to produce the part by a non-simplified production method; or

• when at least one of the selection levels of at least one of the selection criteria corresponds to the second level, the other selection levels of the selection criteria being at the first level, the selection process can not directly determine whether the piece should be performed by the simplified embodiment method.

According to a first characteristic of the selection method, a first family of selection criteria relates to the technical characteristics of the sheet blank used to produce the part, a second family of selection criteria relates to the technical characteristics of the part as formed and / or on the positioning that the piece as intended to be positioned on the vehicle.

According to a second characteristic of the selection method, for the first family of criteria, one or more selection criteria correspond to either: The ratio between the elastic limit and the maximum breaking strength of the sheet blank;

• the percentage of maximum elongation at break of the sheet blank;

• the coefficient of work hardening of the sheet blank; and / or "at the average anisotropy coefficient of the sheet blank.

According to a third characteristic of the selection method, for the second family of criteria, one or more selection criteria correspond to either:

The number of manual finishing operations required in the case where the part is produced according to the simplified production method;

• the positioning of the part on the vehicle according to three levels of

visibility; and or

• the percentage ratio between the height of the room and the greatest length of the room. According to a fourth characteristic of the selection method, the first level of the criterion for selecting the positioning of the part of the second family of selection criteria corresponds to the positioning of the part as masked for an aspect part of the vehicle, the second level corresponds to an appearance part of the vehicle but positioned on an inconspicuous part of the vehicle or positioned on a visible part of the vehicle but whose feasibility tests have shown that the final appearance of a part made according to the simplified embodiment method is satisfactory and the third level corresponds to an aspect part of the vehicle which is impossible to achieve satisfactorily with the simplified embodiment method. Other characteristics and advantages of the invention will appear in the following description of an embodiment of the method according to the invention. To the attached drawings

• Figure 1, previously described, graphically represents the evolution between the cost of a stamping tool for stamping a part and a finishing time on the part as stamped by this tool; FIG. 2 represents, in the form of a flowchart, the various steps of a simplified embodiment of a part according to the invention;

FIGS. 3a to 3d show the state of progress of the part during the various steps of the simplified production method according to the invention; and

FIG. 4 represents, in tabular form, the various criteria and families of criteria making it possible to select the simplified production method or a non-simplified production method.

FIG. 2 represents, in the form of a flowchart, the various steps of a simplified production method 1 of a part 2 (as represented in FIG. 3d). The simplified embodiment method 1 comprises a first step 1 1 and a second step 12 which form preparation steps. These two preparation steps 1 1 and 12 precede a forming step 13, followed by a scribing step 14. A final finishing step 15 makes it possible to finalize the piece 2 with a finish just as necessary depending on the part of the structure of the vehicle for which the part 2 is intended to be positioned. As more particularly explained in the remainder of the description, the simplified production method 1 is more particularly intended to form parts 2 in small quantities, generally a few thousand pieces 2. FIGS. 3a to 3d represent the state of progress of FIG. the part 2 during the different steps of the simplified production method 1 (shown in FIG. 2) of the part 2.

In FIG. 3a is shown a sheet blank 21, which is intended to form the part 2 after the different steps of the simplified production method 1. During the two preparation steps 1 1 and 12 (shown in FIG. 2), the sheet blank 21 is cut and punched. These first two steps are generally done offline, with an operator placing each sheet blank 21 in, respectively, a cutting machine tool and / or in a punching machine tool. Between and after these different steps, chip cleaning operations are also performed on the sheet blank 21. The purpose of these operations is to have a sheet blank 21 of optimized shape for the forming step 13 (shown in FIG. 2), in particular with the formation during the second preparation step 12 of the sheet blank 21, by The pilot holes 23 of the sheet blank 21 are adapted to hold the sheet blank 21 in position during the closing of the press. The optimized shape of the sheet blank 21 and in particular the presence of the pilot holes 23, allow the stamping tool not to include a blank holder. Figure 3b shows a blank 22 of the workpiece 2, as formed, by a single-action type stamping tool from the sheet blank 21 (as shown in Figure 3a). In this Figure 3b, only the punch 24 of the press, which forms a lower shoe, is shown. The press used is a single action type press, having only one direction of movement of the punch 24 and / or the die and having no falling blades. Such a press requires that the used sheet blank 21 has a shape adapted to directly form the blank 22 of the workpiece 2. To maintain the sheet blank 22 in position during the entire stamping step, the pilot holes 23 collaborate. with pawns of the punch 24 (the pions not being represented). The pilot holes 23 guarantee the repeatability of the positioning of the blank 21 in the embossing tool and the repeatability of the positioning of the blank 22 of the workpiece 2 during the scribing step 14 (shown in FIG. 2). The pilot holes 23 are defined outside the so-called noble zone of the part 2. The noble or aspect zone of the part 2 is formed by the parts of the part 2 which are visible after the assembly of the part 2 on the vehicle.

FIG. 3c shows the blank 22 of the piece 2 after the step of forming 13 and as positioned on a support 25 for the scribing step 14. The scribing step 14 comprises a succession of steps of trimming, punching and forming notches on the blank 22. To do this the blank 22 of the part 2 is positioned on the support 25 which allows a three-dimensional positioning of the blank 22 of the part 2 with a pilot index adapted to perform a fretting operation 14 of the laser cutting type 26 of the blank 22. During this scribing step 14 can be removed a portion of the blank 22 of the part 2 which has the pilot holes 23. In Figure 3d is shown the piece 2 after the finishing step. Part 2 is now ready to be stored for assembly on the structure of a vehicle.

The finishing step, which is not shown, consists of operations of dropping parts of the part 2 that would have required a return angle in the stamping tool for such a fall is done automatically during the forming step 13. Also being understood by finishing operations, folding operations that are performed outside the main axis of movement of the press and volume up-take operations. All these operations are done manually by an operator. The invention as described, may also include a variant, in the case where one of the presses of an already existing stamping line can be used in the context of this method of producing parts 2 in small series. In this case, the preparation steps are done offline, the piece 2 is then deposited along the stamping line upstream of the press in question and recovered downstream of this press to receive the step of fretting 14 and finishing 15.

FIG. 4 represents, in the form of a table, the various criteria making it possible to select the simplified production method 1 or a non-simplified production method. According to the invention, a selection method comprises according to two families of selection criteria CS1, CS2:

The first family of selection criteria CS1 relates to the technical characteristics of the sheet blank 21 (shown in FIG. 3a) used to produce the part 2; and "the second family of CS2 selection criteria relates to the geometry of the part 2 to be formed and its positioning on the vehicle.

The two selection criteria families CS1, CS2 respectively comprise four and three selection criteria, each selection criterion comprising three values or ranges of values previously established which correspond to three levels of selections N1, N2 and N3. The first family of selection criteria CS1 comprises four selection criteria that characterize the technical characteristics of the sheet blank 21, namely:

A first selection criterion RMP which corresponds to a ratio between the elastic limit and the maximum breaking strength of the sheet blank 21; · A second selection criterion A1 which corresponds to the percentage of maximum elongation at break of the sheet blank 21;

• A third selection criterion Cf which corresponds to the coefficient of work hardening of the sheet blank 21; and

• A fourth selection criterion Cr which corresponds to the average anisotropy coefficient of the sheet blank 21.

The second family of selection criteria CS2 comprises three selection criteria that define the geometry of the part 2 to be formed and / or its positioning on the vehicle, namely:

A first selection criterion Ft corresponding to the number of manual finishing operations required in the case where the part 2 is produced according to the simplified embodiment method 1; A second selection criterion At which characterizes the positioning of the part 2 on the vehicle according to three levels of visibility; and

A third selection criterion Ht which corresponds to the percentage ratio between the height and the greatest length of the part 2 to be made.

Each of the criteria RMP, Al, Cf and Cr of the first family of selection criteria CS1 includes ranges of values which make it possible to classify, according to the three levels of selections N1, N2 and N3, technical characteristics of the sheet blank 21, as we have:

For the first selection criterion RMP1, three ranges of values RMP1, RMP2 and RMP3 which respectively correspond to the selection levels N1, N2 and N3;

For the second selection criterion A1, three ranges of values AU, AI2 and AI3 corresponding respectively to the selection levels N1, N2 and N3;

For the third selection criterion Cf three ranges of values Cf1, Cf2 and Cf3 which correspond respectively to the selection levels N1, N2 and N3; and

For the fourth selection criterion Cr, three ranges of values Cr1, Cr2 and Cr3 which respectively correspond to the levels of selections N1, N2 and N3.

For the second family of CS2 selection criteria, we have:

• for the first selection criterion Ft:

The first value Ft1 which corresponds to the first selection level N1 and which corresponds to having no manual finishing operation to obtain the part 2 according to the method of simplified embodiment 1;

The second value Ft2 which corresponds to the second selection level N2 and which corresponds to having only one manual finishing operation to obtain the part 2 according to the simplified production method 1; and

The third value Ft3 which corresponds to the third selection level N3 and which corresponds to having at least two manual finishing operations to obtain the part 2 according to the simplified production method 1. for the second selection criterion At:

• the first level At1 which corresponds to the first level of selection N1 and which corresponds to the part 2 as intended to be positioned on the masked vehicle for a part of appearance of the vehicle;

The second level At2 which corresponds to the second level of selection N2 and which corresponds to a part 2 of appearance but intended to be positioned on a not very visible part of the vehicle or intended to be positioned on a visible part of the vehicle but whose tests feasibility have shown that the final appearance of a part 2 made according to the simplified embodiment method 1 is satisfactory; and

• the third level At3 which corresponds to the third level of

selection N3 and which corresponds to a vehicle appearance part 2 which is impossible to achieve satisfactorily with the simplified embodiment method 1.

• For the third selection criterion Ht, we have three ranges of values Ht1, Ht2 and Ht3 which correspond respectively to the levels of selections N1, N2 and N3.

The table below presents the different thresholds independently of the means implemented:

Once the values or ranges of values of the selection criteria of the two families of selection criteria CS1 and CS2 have been established, for each selection criterion, a value Vp of a technical characteristic of the sheet blank 21 or of the part 2 is determined. The value Vp is then listed for each selection criterion, making it possible to obtain the corresponding selection level N1, N2 or N3, so that:

When the selection level of all the selection criteria corresponds to the first selection level N1, it is chosen to produce the part 2 by the simplified production method 1, or

When the selection level of at least one of the selection criteria corresponds to the third selection level N3, it is chosen to produce the part 2 by the non-simplified embodiment method 1.

In the case where at least one of the selections levels of part 2 is at second level N2, the other levels of selections being at the first level N1, then the selection process can not determine directly whether the part 2 must be carried out by the simplified embodiment 1 or not simplified. To do this, tests are carried out. If all the tests are conclusive then one chooses to make the part 2 by the simplified method of realization 1, otherwise the part 2 is carried out by a non-simplified production method. The tests consist, generally in a first step, in analyzing the result of the selection criterion noted at the second level N2 on a simulator. If in doubt after this first analysis, tests on a stamping tool can be performed before the final decision on the process used.

Claims

1. Process for the simplified production (1) of a workpiece (2) for a vehicle, such as a motor vehicle, from a sheet metal blank (21) comprising a plurality of steps (1 1, 12, 13, 14, 15), including a single forming step (13) which consists in using a single stamping press having only one stamping direction, to form a blank (22) of the workpiece (2), characterized in that the sheet blank (2) is held in position during the forming step (13) by means of one or more indexing holes (23) cooperating with one or more pegs (s) ) of the stamping press. 0

2. A method of simplified embodiment (1) of a part (2) according to claim 1, characterized in that the hole (s) indexing (s) (23) is or are formed (s) during a preparation step (1 1, 12) preceding said forming step (13).

3. A method of simplified production (1) of a workpiece (2) according to claim 2, characterized in that the preparation step (1 1, 12) comprises a succession of steps of cutting and punching the blank of sheet metal (21).

4. A method of simplified embodiment (1) of a part (2) according to claim 1, characterized in that the hole (s) indexing (s) (23) is or are formed (s) in a portion of the blank sheet metal (21) which is to be removed o during a fretwork stage (14) which follows the shaping step (13).

5. A method for simplified production (1) of a part (2) according to claim 4, characterized in that the fretwork step (14) is performed by means of a laser-type cutting device with a definition in three dimensions. 5

6. A method of simplified production (1) of a part (2) according to claim 1, characterized in that it comprises a final finishing step (15) comprising at least one manual shaping operation of the blank (22) of the workpiece (2), said forming operation having at least less a deformation operation of a portion of the blank (22) of the workpiece (2) being in a direction of deformation different from the drawing direction of the stamping press.

7. Part (2) intended to form a part of a vehicle, such as a motor vehicle, characterized in that it is performed by a simplified embodiment (1) according to any one of the preceding claims.

8. Selection process between a method of simplified production (1) of a part (2) according to any one of claims 1 to 6 and a method of non-simplified production of said part (2), characterized in that the method of selection comprises at least two selection criteria (RMP; Al; Cf; Cr, Ft; At; Ht), each selection criterion (RMP; Al; Cf; Cr, Ft; At; Ht) decomposing into three ranges; predefined values, each range corresponding, respectively, to one (N1; N2; N3) of three selection levels (N1, N2, N3), for each selection criterion (RMP; Al; Cf; Cr, Ft; At; ; Ht), a value (Vp) of a technical characteristic of the workpiece (2) is determined, said value (Vp) being then listed in one of the corresponding value ranges of each selection criterion (RMP; Al; Cf; Cr, Ft; At; Ht), so that: · when the level of selection (N1, N2, N3) of the set of criteria of e selection (RMP; Al; Cf; Cr, Ft; At; Ht) of the workpiece (2) corresponds to the first selection level (N1), the workpiece (2) is selected by a simplified production method (1), or

When the selection level (N1, N2, N3) of at least one of the selection criteria (RMP; Al; Cf; Cr, Ft; At; Ht) corresponds to the third selection level (N3), to produce the workpiece (2) by a non-simplified production method.

9. A selection method according to claim 8, characterized in that when at least one of the selection levels (N1; N2; N3) of at least one selection criteria (RMP; Al; Cf; Cr, Ft; At; Ht) is at the second level (N2), the level of selections (N1; N2; N3) of the other selection criteria (RMP; Al; Cf; Cr, Ft; At; Ht) being at the first level (N1), the selection process can not directly determine whether the part (2) has to be performed by a simplified production method (1).

10. A selection method according to claim 8 or 9, characterized in that a first family (CS1) of selection criteria (RMP; Al; Cf; Cr) relates to the technical characteristics of the sheet blank (21) used to producing the part (2) and a second family (CS2) of selection criteria (Ft; At; Ht) relates to the technical characteristics of the part (2) as formed and / or to the positioning of the part (2) as intended to be positioned on the vehicle.

1 1. A selection method according to claim 10, characterized in that the first family of selection criteria (CS1) comprises: * a first selection criterion (RMP) which corresponds to a ratio between the elastic limit and the maximum resistance to the rupture of the sheet blank (21); and or

a second selection criterion (Al) which corresponds to the percentage of maximum elongation at break of the sheet blank (21); and / or * a third selection criterion (Cf) which corresponds to the coefficient of work hardening of the sheet blank (21); and or

a fourth selection criterion (Cr) which corresponds to the average anisotropy coefficient of the sheet blank (21).

12. Selection process according to claim 10, characterized in that the second family of selection criteria (CS2) comprises:

* a first selection criterion (Ft) which corresponds to the number of manual finishing operations necessary in the case where the piece (2) is produced according to the simplified embodiment method (1); and or

a second selection criterion (At) which corresponds to the positioning of the part (2) on the vehicle according to three levels of visibility; and or

a third selection criterion (Ht) which corresponds to the ratio in percentage between the height and the greatest length of the piece (2).

13. Selection process according to claim 12, characterized in that for the second selection criterion (At) of the second family of selection criteria (CS2):

the first level (At1) corresponds to the positioning of the part (2) as masked by an aspect part of the vehicle;

* the second level (At2) corresponds to a piece (2) of appearance of the vehicle but positioned on a not very visible part of the vehicle or positioned on a visible part of the vehicle but whose feasibility tests have shown that the final appearance of a workpiece (2) made according to the simplified production method (1) is satisfactory; and

* the third level (At3) corresponds to a piece (2) of appearance of the

vehicle that is impossible to achieve satisfactorily with the simplified production method (1).