DE2344803A1 - PROCESS FOR AUTOMATIC DESIGN OF SEQUENCE CUTTING TOOLS AND ARRANGEMENT FOR PERFORMING THE PROCESS - Google Patents

Description

S.Plainfield, New Jersey 07080 USA

Process for the automatic design of follow-up cutting tools and arrangement for implementation of the procedure

The invention relates to a method of automatically designing sequential cutting tools, and more particularly to a method that is used to determine whether such tools are not present at a particular workstation suitable dividing lines are present and an arrangement for carrying out this process.

In U.S. Patent Application Serial Number 66,533, dated Aug. 24, 1970, there is an automatic design method of sequential cutting tools described in which the various recesses along the successive Workstations of the tool are distributed according to a predetermined distance so that according to the Cutting forces of the recesses a sufficient amount of metal between the recesses is made possible.

Schw / Ba

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In some tool designs, this aspect alone is a sufficient criterion for the arrangement of the . Recesses. This applies, for example, when the machining process involves the manufacture of a complicated isolated hole in the cutting tool portion, as in electrical discharge machining (EDM) or with drilling processes and with hand-filing or broaching processes. However, it is often desirable split the tool recess and the tool segments by grinding each section with a grinding wheel produce so that two or more segments of the cutting tool each have a portion of the circumference of the contain certain recess. If all of these segments are put together properly, then they will all border on that Recess, which then has several dividing lines emanating from it. These dividing lines can lead to the outer edges of the cutting tool, or they can end at other recesses in the cutting tool.

The point or points on the circumference of the recess at which the dividing lines are located are from machining points of view and determined by the shape of the recess. It is not possible to separate a recess in such a way that Deep or inaccessible depressions arise in one of the sections, as a grinding wheel is inserted into these depressions cannot be introduced. For example, a rectangular one running horizontally in the longitudinal direction would be Recess divided by a horizontal line through the left and right ends. Likewise, a vertically high, rectangular recess divided by a vertical line through the top and bottom. More complicated Shapes can generally require more than two separation points. Moreover, the dividing line generally goes along the

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Cutting point at right angles from the circumference to the edge, so that the creation of acute angles or corners is avoided at the cutting tool sections.

Since the cutting tool recesses cannot be separated at will, there are certain arrangements the recesses in the cutting tool not possible. These are the arrangements that geometrically do not allow that a dividing line emanating from a recess in the circumferential line directed towards it of a second adjacent one Recess ends. For example, the two recesses described above can be close to each other be arranged, as the vja outgoing a recess horizontal dividing line cannot end at the side of the second recess facing it. It has to be one from the top vertical dividing line at the bottom or a suitable additional recess (or recesses) are added, This enables a correct termination of the horizontal dividing line. In this case, the vertical dividing line due to the outer trim at the top and bottom edges end of the cutting tool assembly.

Also, the two recesses can not be made close to each other, since the vertical dividing line through the vertically high recess cannot end at the side of the second recess facing it. Here too would the attachment of a suitable additional horizontal dividing line or an additional recess to a allowed construction. It should be noted, however, that such additional parting lines or recesses may do not fit in the space between the two original recesses, so that the entire intended Arrangement is not feasible.

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So far, the design of cutting tools has been carried out entirely by trained tool designers, who made mental decisions based on their knowledge and experience «

With the aid of the invention, a method and an arrangement for automatically arranging recess perimeter lines are intended be created within the structure of a cutting tool, with the proximity and direction of parting lines, which "emanate from these recesses, are taken into account. With the aid of the invention, the result of a yes-no test is to be taken into account for a trial position of a circumferential line in the form of an electrical signal from an independent one Facility displayed v / earth which is adaptably inserted into various different constructions used in automatic cutting tool design.

An embodiment of the invention is shown in the drawing shown. Show in it:

1 shows a block diagram of the overall arrangement according to Invention,

FIG. 2 is a block diagram of an analyzer used in FIG circuit,

3 shows a schematic circuit diagram of one of the analyzer units the analyzer circuit of Figure 2,

Fig. 4 is a block diagram of the circuit used in Fig. and control unit and

Fig. 5 is a diagram to illustrate the operation of the Analyzer units of Fig. 3.

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In automatic cutting tool design, the various tool recess outline shapes must be longitudinal of the cutting tool can be distributed by assigning each circumferential shape to a specific work level. These Assignment consists in the circumferential shape in the horizontal direction by an integer number of feed distances to move. The advance distance is equal to the distance along which the metal strips during the operation of the finished one Cutting tool is moved horizontally.

The number of parting lines emanating from a recess can be zero (when making a hole by drilling or by electro-erosive machining), 2, 3 or 4. The presence of only one blowout from a recess The dividing line is irrelevant, since this does not allow the metal segments surrounding the recess to be separated provides an access for a grinding wheel to form the recess.

According to Figure 1 contains the overall arrangement to be described here a memory 10 for storing coordinate signals showing each recess circumference shape and number and direction Define dividing lines from it. The memory can also be used to store a perimeter shape, by adding a corresponding to the numerical product of the feed distance and the number of work stages Size is assigned to the x-coordinate signals of a specific work level.

A switching and control unit 16 is also provided, with the aid of which the coordinates and the separating surfaces appropriate signals can be passed to an analyzer circuit 18 so that it can be determined whether any Circumferential shapes have incompatible separating conditions at their mutually facing end edges.

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The advance is stored in the memory device 12 and the work step number is in a multi-cell device 14, the number of cells of which corresponds to the number of storage locations in memory 10.

The arrangement of Fig.1 can with the help of other devices used in a sequential process by which these other devices the number of stages of the set different circumferential shapes and use the output signals of the arrangement of Fig. 1 to to determine whether the arrangements of the circumferential shapes indicated by the step numbers are due to a mismatch the dividing lines is not possible, as described above. This exam is typically additional applied to other tests that deal with the geometric closeness of the circumferential forms and with other factors (as described in U.S. Patent Application Serial Number 66,533, referenced above) are ultimately concerned with this an arrangement is selected that meets all the conditions for the cutting tool design.

With the arrangement described here, the coordinates of the circumferential shapes can take many forms with varying degrees of complexity. For the purpose of explanation, a circumferential shape can be appropriately represented by four coordinates corresponding to the maximum and minimum x-coordinates and the maximum and minimum y-coordinates of the circumferential shape. These coordinates are shown in Fig.1 by the symbols Χ _χ , Y ^, Υ _χ and Y ^. These numerical coordinates can be stored as capacitor cell voltages proportional to the coordinates (or as other signals), or they can be reproduced in digital form and stored in binary form in a magnetic core memory or in other signal forms. For the operation of the arrangement described here, the

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Coordinates stored as analog voltages which are proportional to the numerical value of the coordinates.

The information that describes the areas from which the Dividing lines can also reasonably be expressed by considering only four directions, which are labeled right, left, top and bottom (in Fig. 1 R, L, T and B, respectively). The to represent · this Directions used four memory cells can essentially be applied in a binary manner, where a non-zero voltage indicates a dividing line emanating from the specific area, while a voltage with the value zero indicates the fact that no dividing line extends from this end face. Thus becomes a positive, non-zero voltage in stored in the corresponding memory cell.

It should be noted that generally more than four coordinates in four directions can be used. In the present However, in the case of a total of eight memory cells to represent their peripheral shape and data describing their associated dividing lines.

It should also be noted that the values are not actually stored in the memory cells for this purpose as long as they are available to the arrangement when required. For example, the values from the basic description the complete circumferential shape coordinates by scanning the circumferential shape each time again can be derived if required. This derivation of the maximum and minimum values is by sampling described in detail in the above-mentioned United States patent application.

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The overall arrangement is shown in Fig.1. The values describing the coordinates and the separating line directions of each circumferential shape are stored in the memory 10, which consists of a memory cell array which is organized in groups of eight cells each. These eight cells contain the values for the horizontal maximum and the horizontal minimum (Χ _χ and X _n ) as well as the vertical maximum and the vertical minimum (Y and Y) and the indicators for dividing lines in the four directions right, left, top and stored below (R, L, T and B).

The memory 10 is via the switching and control unit 16, which contains, among other things, a simple multiplying and adding unit, connected to the analyzer circuit 18. The Switching and control unit 16 routes signals from and to the various memories 10, 12 and 14 of the input sclera 20 and the analyzer circuit 18.

For a more detailed description of the switching and control unit 16, reference is now made to FIG. The switching and control unit 16 can act one in two directions Sampler 22 included (its input and output terminals to simplify the description of the unit are given in a simplified manner), through which the circumferential shape Characteristic input information from terminal 20 one after the other in groups 10a, 10b, 10c .... and 14a, 14b and 14c ... the memories 10 and 14 are stored if-the scanner 22 is indexed successively will. The feed is also in the feed storage saved.

In a next operational sequence, the actual coordinates of the circumferential shapes are determined. It means that Each circumferential shape in the horizontal direction to hers

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Experimental work stage is brought. This is achieved in that the identification information of the initial form is sequential can be read from the memories 10 and 14 with the aid of the scanner-22. Each work level number is derived from the Memory 14 is applied to a multiplication unit 24 via a switch 26 which is closed at this point in time. That Feed signal is the multiplier 24 via a Line 28 supplied. The resulting product, which is equal to the distance, shifted over the horizontal coordinates must be applied to an adding unit 30 via a line 32. Also ground to the adding unit 30 the initial horizontal coordinates of the circumferential shape, which are scanned by the scanner 22 at this point in time, are applied. These coordinates that define the horizontal position of the recess or the circumferential shape when they are at the first Working stage of the cutting tool is located via the switch 36, which is closed at this time, and via a Line 34 applied. The resulting sum, which is equal to the horizontal coordinates of the perimeter shape that leads to the is moved from the number stored in the memory 14 specified workstation, is via the switch 38 and the scanner 22 is re-entered into the memory 10. When the scanning process is complete, all coordinates are horizontal any initial shape with a non-zero workstation number to their assigned workstation number moved and then re-entered into memory. In some use cases, a Circumferential form as long as not assigned to a work level number, until it's ready for the exam. In other use cases, all scope forms are work level numbers from the start assigned; With the help of the arrangement described here, it should be determined whether recesses with not matching dividing lines are present.

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In a next step, the actual test of one or more of the circumferential forms is carried out in order to determine whether there are inconsistent dividing lines. When checking a predetermined circumferential size, about a circumferential shape stored in the memory cell group 10c, a presetting unit 40 is used to to switch the scanner 22 for the selection of this circumferential shape and to switch them on via a line 44 and one switch 46 closed at this point in time in a register 42.

The scanner 22 is then reset so that all of the circumferential shapes stored in memory 10 along with their associated work level numbers stored in memory 14. The work level numbers are checked sequentially in units 48 and 50 to determine if the is currently being sampled Circumferential shape (1) has been assigned to a work level number zero (which, according to the above, means that this circumferential shape should not be checked at this point in time), or (2) whether this circumferential shape is the same, which was previously saved in register 42. If the circumferential shape currently being scanned does not meet any of the test conditions specified above met, it is entered via a line 54 into a register 52, whereupon it is in the analyzer circuit 18 is compared with the circumferential shape stored in register 42. The comparison process is carried out in The connection with FIGS. 2 and 3 is also described in more detail below. Each circumferential shape in the memory 10 can with the other circumferential forms stored therein are stored in the manner described.

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In summary, the switching and control unit 16 works as follows:

1 · The the coordinate and dividing line directions of each Signals expressing the circumferential shape are transmitted to corresponding memories 10 and stored there.

2. The feed and work step numbers of each circumferential shape are transferred from the input terminal 20 to the corresponding memories 12 and 14.

3. The scanner 22 scans the cell groups describing the coordinates and the dividing line directions as well which describe the work level number of each scope form Cells. In each group, the switching uru control unit 16 detects the value of 2x coordinates and adds them this becomes the product of the feed number and the work step number, which is achieved with the aid of the multiplication unit 24 and the adding unit 30 is achieved in the switching and control unit. At this point, enter the 10 stored coordinates indicate the arrangement of the circumferential shapes along the surface of the cutting tool. In the test those scope forms are not involved, their work level number has the fourth zero.

4.Dßr scanner 22 scans the coordinates and the parting line directions Descriptive groups from, and diverts the appropriate signals to the analyzer circuit 18, so In this circuit a comparison can be made with the corresponding signals of the circumferential shape just tested, which are stored in register 42, a signal from presetting unit 40 being able to indicate which circumferential shape number is to be used constantly for the test table.

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The switching and control unit 16 selects each group (with the exception of those with the level only zero and the comparison group itself).

The analyzer circuit 18 does not emit an output signal if all comparison processes are valid combinations of result in mutually directed dividing lines. If an invalid combination occurs, it becomes an output signal generated indicating that the test position of the test perimeter shape does not match with other perimeter shapes, since opposing edges may or may not have parting lines in a mismatched manner exhibit.

The internal operation of the analyzer circuit 18 and its interconnection with registers 42 and 52 continues below in connection with a discussion of the use of this arrangement in automatic design of Cutting Tools "will be discussed below. Typically are at an intermediate stage in the cutting tool design process some circumferential shapes have been placed in a final work stage of the tool. Other original forms of capture, (the

are marked in the level number zero), have not yet been classified, and one of these circumferential forms will tested on a trial basis at various levels of work in order to determine v / o it fits. The first test can be inserted on the basis of unity with others Circumferential shapes with regard to the geometric distance, the material strength or with regard to both Parameters are executed. Once a trial work step has been found, the one that relates to the previous one Investigation is permitted, the arrangement described here is used to ensure that

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the experimental classification of the specific circumferential shape is also permissible with regard to the adaptation of the dividing lines .

How the connections generated by the switching and control unit are established in more detail is shown in FIG. The registers 42 and 52 correspond to the comparison group or one of the other groups (for example the group 10c) from the memory 10. The connections between different cells in the registers 52 and 52 with the terminals of four internal analyzer units to 62 are indicated by schematic wiring lines for the first analyzer unit 56 shown; in the interest of clarity of the illustration, the connections to the three other analyzer units 58 to 62 are indicated by a label on the terminals of the analyzer units, which shows which memory cell is connected to this terminal. The outputs of the four analyzer units are connected to a common output terminal 64 via diodes.

The circuit diagram of the analyzer units 58 to 62 is shown in FIG. Each analyzer unit contains 8 input terminals 66 to 80, which can be seen in FIGS. 2 and 3. The input terminals are connected to differential amplifiers 82 to 90, each of which delivers an output voltage that is proportional to the algebraic difference between the input signals at its plus and minus input terminals. The output signal of differential amplifier 82 is therefore only positive if the signal at terminal 66 is algebraically greater than the signal at terminal 68 .

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The terminals 78 and 80 are cross-connected to the inputs of the differential amplifiers 88 and 90, so that one of these two amplifiers produces a positive output signal when the signals at terminals 78 and 80 are different regardless of which of the signals is larger than the other. Thus, the amplifiers form 88 and 90 have an antivalence function.

The outputs of the amplifiers 82 to 90 are each connected to clamping diodes and to a clamping voltage supply Vp via small, equally large resistors R. Thus, the output voltage does not exceed the voltage Vp at this point, even if the input signals differ by a significantly larger amount than the minimum difference corresponding to the output voltage Vp of the terminal voltage supply. The five clamped outputs of the differential amplifiers 82 to 90 are connected to a common connection point 102 via five identical resistors R. This connection point is connected to the output via a diode 104 and to a negative reference voltage -V ^ via a resistor Rj. The fourth of the resistors R. and _R.sup.3 are selected so that a clamped output voltage with the value V _c of four or more of the five differential amplifiers at the connection point 102 generates a positive voltage, so that a signal is transmitted through the output diode 104 as a result can be. For example, if the voltage Vp has the value 1 volt and the voltage -V _{n has} the V / ert -3.5 volts, then resistance values of 1000 ohms for the resistors R _A. And R _{ß are} suitable values for this purpose.

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The analyzer units shown in FIGS. 2 and 3 work as follows: If, according to FIG. 5, the circumferential shape B lies completely on the left side of the circumferential shape Λ, then no circumferential shape is completely above or below the other and the mutually facing edges do not match Parting line conditions (ie a parting line of one circumferential shape runs in one direction to the other circumferential shape without a corresponding parting line running back); the analyzer unit 56 emits an output signal. In FIG. 5, Χ · _{Ν is} greater than Χ _βχ , which indicates that the circumferential shape B lies completely on the left side of the circumferential shape A. This is determined with the aid of the differential amplifier 82, as a result of which at least a voltage of 1 volt is applied to the connection point 102 (assuming the values given above as an example), since the conditions Y ^> Y ™, and Y-rv-jr> Y..J exist, no circumferential form is completely above or below the other. These two conditions are detected by differential amplifiers 84 and 86, thereby applying at least two additional volts to junction 102. Since there is no dividing line R _ß (ie a dividing line emanating from the right side of the circumferential shape B) and a dividing line L _{A is} present (ie a dividing line emanating from the left side of the circumferential shape A) the non-equivalence condition of the differential amplifiers 88 and 90 is fulfilled, whereby an additional voltage of one volt is applied to junction 102 for a total voltage of four volts. Thus, the output terminal 64 is supplied with an output voltage indicating that a mismatched condition has occurred. This condition can be exploited in several ways, as described above.

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The three other analyzer units 58 to 62 generate an output signal when a similar situation exists, with which the circumferential shape B is to the right of the circumferential shape A, below the circumferential shape A or above the circumferential shape A, as on closer inspection of FIG can be.

It will be appreciated by those skilled in the art of electronics and control that performing the above tests when using fully digital facilities and when calculating and storing all used in the analog circuit Values in read-write memory under control by hard-wired or stored-programmed step control signals is possible. The extension of the example with four coordinates to the use of additional coordinates and separating line directions only requires the addition of similar circuit elements in the analog case or the further repetition of processes in the purely digital case.

Claims

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Claims (1)

Claims M. J arrangement for controlling the application of divided cutting tool recesses in a subsequent cutting tool, each recess in the form of groups of circumferential shape coordinate signals which define predetermined coordinates of the circumferential shape of the recess, and in the form of parting line direction signals which define areas of the recess peripheral shapes from which parting lines emanate, are described, labeled; by first register means for storing a first group of circumferential shape coordinate signals and parting line direction signals corresponding to a first divided cutting tool recess, second register means for storing a second group of peripheral shape coordinate signals and parting line direction signals corresponding to a second divided cutting tool recess and analyzer devices which determine the upper signals as a function of the first and second peripheral shape coordinates divided cutting tool recess corresponding to the first signal group is inexpediently attached with respect to the divided cutting tool recess corresponding to the second signal group because there are incompatible dividing line conditions. 2. Arrangement according to claim 1, characterized by first storage devices for storing a plurality of groups of circumferential shape coordinate signals and parting line direction signals including the first and second Groups of circumferential shape coordinate signals and parting line direction signals, selection devices for selecting the first group of circumferential shape signals from the 409812/1131 23U803 a plurality of groups and for storing the first group in the first registers and scanners for scanning the remaining groups and for repeatedly applying these remaining groups to the second register devices, the analyzer means sequentially depending on the content of the first and second register means determine whether the split cutting tool recess corresponding to the first signal group with respect to the other divided cutting tool recesses corresponding to the other groups because they do not match Separation line conditions are inexpediently arranged. 3. Arrangement according to claim 2, characterized in that the scanning devices contain circuit devices which initially one after the other in the first storage devices store plural groups of initial peripheral shape coordinate signals corresponding to the plural groups of peripheral shape coordinate signals, respectively correspond to that second storage means store a plurality of stage numbers each corresponding to the Corresponding step numbers of the split cutting tool recesses identified by the multiple initial circumferential shape coordinate signals that third storage means indicate the advance distance between stages of the follower cutting tool store and that allocation devices depending on the initial circumferential shape coordinate signals, the step numbers and the feed distance, the horizontal coordinates of each initial group of circumferential shape coordinate signals assign to the appropriate stage such that the resulting group of signals corresponds to the circumferential shape coordinate signals for this level. 4. Arrangement according to claim 3, characterized in that the allocation devices multiplier units for successive Multiply the step numbers by the feed 4 0 9 812/1131 spacing included, the successive products, each in the horizontal spacing correspond to the horizontal coordinates of the initial groups, are to be assigned, and that the assignment devices Adding units to the consecutive Adding the successive products and the last-mentioned horizontal coordinates to generate the several Contain circumferential coordinate signals. Arrangement for controlling the application of split cutting tool recesses in a subsequent cutting tool, each recess in the form of groups of circumferential shape coordinate signals, define the predetermined coordinates of the circumferential shape of the recess, and in the form of parting line direction signals, Define the surfaces of the recess circumferential shapes from which dividing lines start, described are characterized by first register means for storing a first group of circumferential shape coordinate signals and parting line direction signals corresponding to a first split cutting tool recess, second register means for storing a second group of circumferential shape coordinate signals and parting line direction signals corresponding to a second divided cutting tool recess and analyzer devices, with circumferential shape comparison devices for comparing the first and second circumferential shape coordinate signals c for determination the relative spatial relationship of the first and second split cutting tool recesses to one another, with Parting line comparison means for comparing the first and second parting line direction signals to the Determination of whether a parting line is directed against the first or the second cutting tool recess without that there is a corresponding backward dividing line, and with decision-making facilities that are dependent AQ9812 / 1131 determine of the circumferential shape comparison devices and the parting line direction comparison devices, whether the divided cutting tool recess corresponding to the first signal group with respect to that of the second Signal group corresponding split cutting tool design due to the presence of mismatches Dividing line conditions is inappropriately placed. 6. Arrangement according to claim 5, characterized in that the circumferential shape comparison devices have several groups of comparison units which each determine whether a predetermined spatial relationship between the first and second cutting tool recesses are present. 7. Arrangement according to claim 6, characterized in that the dividing line comparison devices have several non-equivalence Contain units that are each assigned to the groups of comparison units. 8. An arrangement according to claim 7, characterized in that the decision devices have several determination units included, each as a function of the multiple groups of comparison units and of the plurality of non-equivalence units determine whether in one of the predetermined spatial relationships mismatching conditions exist between the first and second cutting tool recesses. 9. Method of controlling the placement of split cutting tool recesses in a subsequent cutting tool, each recess in the form of groups of circumferential shape coordinate signals, define the predetermined coordinates of the circumferential shape of the recess, and in the form of parting line direction signals, the areas of the recess perimeter shapes 409812/1131 define, from which dividing lines proceed, are described, characterized in that a first group of circumferential shape coordinate signals and parting line direction signals corresponding to a first split cutting tool recess that a second group of circumferential shape coordinate signals and parting line direction signals is stored is stored corresponding to a second split cutting tool recess, and that the first and then examines second circumferential shape coordinate signals whether the split cutting tool recess corresponding to the first signal group with respect to that of the second signal group corresponding divided cutting tool recess due to the presence of mismatches Dividing line conditions is inappropriately placed. 10. The method according to claim 9, characterized in that several groups of circumferential shape coordinate signals and Parting line direction signals including the first and second groups are stored that from the several groups, the first group of circumferential shape coordinate signals is selected that the rest. groups are scanned from the several groups and that it is examined whether the corresponding to the first signal group divided cutting tool recess with respect to & r the remaining signal groups corresponding to other divided Cutting tool recesses inexpedient due to the existence of mismatching parting line conditions is placed. 11. The method according to claim 10, characterized in that initially several groups of initial perimeter shape coordinate signals are stored ', each corresponding to the plurality of groups of circumferential shape coordinate signals that several Level numbers are stored which correspond to the level numbers of the 40981 2/1131 split cutting tool recesses indicated by the plurality of initial circumferential shape coordinate signals are that the displacement distance between steps of the follower tool is stored and that as repeated Reaction to the initial circumferential coordinate signals, the step numbers and the feed distance, the horizontal coordinates are assigned to each initial group of circumferential shape coordinate signals of their respective level, so that the resulting signal group corresponds to the circumferential shape coordinate signals for this stage. 12. The method according to claim 11, characterized in that in the assignment one after the other, the step numbers with the feed distance are multiplied, where the successive products correspond to the horizontal distances and the horizontal coordinates the initial groups are to be assigned, and that in the assignment the successive products and the last-mentioned horizontal coordinates are added one after the other to achieve the plurality of circumferential shape coordinate signals will. 13. Method of controlling the placement of split cutting tool recesses in a sequential cutting tool, each recess in the form of groups of circumferential shape coordinate signals, the predetermined coordinates of the circumferential shape of the recess define, and in the form of parting line directional signals defining areas of the recess circumferential shapes of which parting lines emanate, are described, characterized in that a first group of circumferential shape coordinate signals and parting line direction signals corresponding to a first divided cutting tool recess are stored, that a second group of circumferential shape coordinate signals and parting line direction signals divided according to a second one Cutting tool recess is saved that during the investigation of the first and second circumferential shape coordinate signals and the first and second parting line direction signals first and second 4 0 9 8 12/1131 Circumferential shape coordinate signals for determining the relative spatial position of the first and second divided cutting tool recesses are compared with each other, the first and second Parting line direction signals are compared to each other to determine whether one against the first or the second mold recess is directed dividing line, without a corresponding backward directed Parting line exists, and according to the circumferential shape comparing step and the parting line direction comparing step it is determined whether the divided cutting tool recess corresponding to the first signal group with respect to the divided cutting tool recess corresponding to the second signal group is not due to the presence matching parting line conditions is inappropriately placed. 14. The method according to claim 13, characterized in that, in the comparison step, several groups of comparison steps are carried out, in each of which it is determined whether there are predetermined spatial relationships between the first and second cutting tool recesses. 15. The method according to claim 14, characterized in that There are several non-equivalence steps in the comparison step which are each assigned to the several groups of comparison steps. 16. The method according to claim 15, characterized in that several determinations are carried out in the decision-making step, each of which is dependent on the several Groups of comparison steps and from the multiple non-equivalence steps it is determined whether the separating line condition does not match in one of the predetermined spatial relationships between the first and second cutting tool recesses is present. 409812/1131 Lee rVe i t e