FI89350B - Process and device for cutting glass sheet blanks - Google Patents

Abstract

A device for cutting glass sheet blanks in accordance with a given contour line includes a cutting machine 2 for cutting the contour line in the glass sheet blank, an edge-crushing machine 4 for separating the edge area, which has been detached by the cut, from the glass sheet blank, and a grinding machine 6 for smoothing the separated edge of the glass sheet blank. The grinding machine 6 comprises two grinding heads which simultaneously grind the opposite edges of the glass sheet blank. A conveyor 8 brings the glass sheet blank to each of the said machines for implementing their respective functions, and a computer-controlled control system 28 controls the three machines in accordance with digital data files which are prepared for each machine. <IMAGE>

Description

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Method and apparatus for cutting sheet metal blanks.

For the purposes of this Regulation, the glassware shall be glazed.

The invention relates to a method and an apparatus for cutting a sheet blank according to a defined contour. The general features of the method are set out in the introduction to the appended claim 1. The apparatus includes a cutting machine for making a contour incision in a blank; an edge crushing machine vii1 for separating the edge portion outside the second curved outline from the glass sheet blank;

The invention is particularly useful for cutting sheet metal blanks in the manufacture of motor vehicle windshields. Therefore, the invention will be described below in connection with this application. The manufacture of motor vehicle windshields first involves cutting the outline of the windshield into the blank, separating the edge portion outside the cutting line from the blank, and grinding the edge of the separated blank. The glass blank is then bent to the required shape and subjected to a heat treatment. In the manufacture of laminated windshields, two such glass blanks are joined together by a transparent film.

Today, cutting, edge separation, and grinding operations are usually performed by hand, with the aid of patterns followed by a tracking roller. Recently, numerically controlled (CNC) machines have been developed in which the operation is controlled by digital information, which has been handcrafted using a digitization table. Although such CNC controlled machine tools are used, grinding is still performed using a pattern tracking roller. However, FR application 2,476,059 discloses a separate grinding machine with two grinding heads 2,893,350 which is controlled numerically by a contour-based file. However, this separate machine is not connected to a production line where all three production steps can be performed automatically, i.e. cutting, edge stripping and grinding.

U.S. Pat. No. 4,698,088 discloses an automatic production line forming apparatus in which contour cutting and cutting edge grinding are performed on machines mechanically coupled together so that both machines can be controlled by common numerical control to move simultaneously and in the same phase along a desired numerically defined contour. This arrangement substantially reduces the production capacity of the device, which is determined by the grinding speed. Contour cutting can typically be performed in about half the time of grinding the cut edge.

The object of the invention is to provide an automatic method and apparatus for cutting blade blanks of the above-mentioned type, in which the operating controls of the cutting and grinding machine are improved so that the production capacity of the entire production line is substantially increased.

This object is achieved by the method according to the invention in that a digital contour file and a digital grinding file are produced on a computer from a digital contour file representing a certain contour, and that the cutter and its various operations are controlled by , that both grinding heads of the grinder grind the opposite edges of one glass plate simultaneously.

Device-specific features are set out in the appended claim 2.

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It is essential for the optimal operation of the entire production line that the speed of movement of the grinding heads along the edge to be sanded can be selected independently of the speed of movement of the cutting head. For this purpose, the cutting machine 1a and the grinding machine have mechanically separate drive units, which are controlled by their own control file! 1 1 aan.

In the method and device according to the invention, the drives of the cutting machine and the grinding machine are thus mechanically separate from each other and their controls are independent of each other, even though they simultaneously work on a similar contour. However, the control is based on a common contour file.

An outline digitizing device 1 can be connected to the production line for sensing the contour of a model or drawing of a blank and for producing a digital contour file. A computer belonging to the control system of the device is programmed to use said digital contour file to produce a digital cut file and a digital grind file.

The invention makes it possible to produce glass sheet blanks cut and ground at a certain contour on a fully automatic production line with a high production capacity and a short set-up time. This short set-up time (e.g. on the order of 5-15 minutes in a typical system) allows the device to be used efficiently when producing glass sheet blanks in small batches as well as in large batches. The invention also makes it possible to automatically digitize new models, and to maximize the utilization of raw materials.

The invention is particularly useful when implemented as a fully automatic production line, in which the edge crushing machine between the cutting machine and the grinding machine is also controlled by a control file formed from the same digital contour file. However

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the invention also makes possible a modular construction in which individual machines can be efficiently used as separate module units with other units in the production line.

Other features and advantages of the invention will become apparent from the following description, in which the invention is described by way of example with reference to the accompanying drawings, in which Figure 1 shows axonometrically an embodiment of a device according to the invention for cutting a sheet blank according to a defined contour; Fig. 2 schematically shows the overall control of the device according to Fig. 1; Fig. 3 shows a transfer crane of the device according to Fig. 1 for transporting workpieces from one machine to the next; Fig. 4 schematically shows the control of the transfer crane according to Fig. 3; Fig. 5 shows in axonometric view in more detail the cutting machine of the device 1 according to Fig. 1 for making an incision in a glass sheet blank according to a defined contour and also for digitizing the contour of a new model; Fig. 6 schematically shows the control of the cutting machine according to Fig. 5; Fig. 7 shows the structure of an edge crushing machine included in the apparatus of Fig. 1, for separating a cut edge portion 89350 from a sheet blank; Fig. 8 shows in more detail a method of controlling the alignment of the burners of the edge crusher of Fig. 7; Fig. 9 schematically shows the control of the edge crushing machine according to Fig. 7; Fig. 10 shows in more detail the structure of the grinding machine of Fig. 1 for smoothing the edges of a separated sheet blank; Fig. 11 shows a control diagram of the grinding machine according to Fig. 9; Figures 12a-12e show different operating modes of the device assembly of Figure 1.

Figure 13 shows the coordinate system used to control these functions; Fig. 14 is a flowchart illustrating the operation of a central computer in the digitizing (or teaching) mode of operation of Fig. 12a; Fig. 15 is a flowchart illustrating the operation of a CNC computer in the digitizing (or teaching) mode illustrated in Fig. 12a, the diagram shown in Fig. 15a helping to understand this mode of operation; Figs. 16a to 16c together form a flowchart illustrating the operation of the central computer in the process operation mode of Fig. 12b; and Fig. 17 shows a diagram to help understand the grinding operation.

The device shown in Fig. 1 of the drawings is specially designed for cutting glass sheet blanks GB according to a defined contour, for use in the manufacture of vehicle windscreens. The apparatus includes an incision cutting machine, generally designated 2, for cutting the outline of a glass sheet blank GB according to a pre-digitized model, or for digitizing a new model; an edge crushing machine, generally indicated by reference numeral 4, for separating the cut edge area from the glass sheet blank GB; and a grinding machine, generally indicated at 6, for smoothing the edges of the separated glass sheet blank.

The device shown further comprises a transfer crane, generally indicated by reference numeral 8, for transporting glass sheet blanks GB from one machine to the next; a loading aid system (not shown) at the line inlet end for loading the glass sheet blanks from the storage bundle, or two different bundles, to a conveyor transporting the glass sheet blanks to the cutting machine 10; and a side crane, generally designated 12, at the outlet end of the line.

The side crane 12 is supported by a frame of a transfer crane 8 in an extension 14 with two rails 16. The side crane 12 includes a vertical frame structure 18 arranged with sliders 20 to move along the rail 16 and a horizontal frame structure 22 supporting a handling device 24 with vacuum heaters 26 for glass plates. for transporting from the grinding machine 6 to the next stations of the production line (not shown) where bending, heat treatment and lamination operations are performed to produce finished windshields.

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The invention according to the application relates in particular to the structure and operation of a cutting machine 2, an edge crushing machine 4 and a grinding machine 6, as well as to the structure and operation of a transfer crane 8 which transports glass sheet blanks from one machine to the next. Accordingly, the remainder of the description focuses on these features of the device of Figure 1, which are further illustrated in the remaining drawings.

The overall operation of the machine is controlled by a central computer 28 comprising a keyboard 30 and a display 32. The cutting machine 2, the edge crushing machine 4 and the grinding machine 6 are each equipped with their own CNC (computerized numerical control) computer (not shown in Fig. 1) which controls the operation of the corresponding machine. are under the control of the central computer 28. In addition, each of these machines, as well as the transfer crane 8, are equipped with a programmable logic controller (PLC), as described in more detail below.

Figure 2 schematically shows the overall control of the cutting machine 2, the crushing machine 4 and the grinding machine 6 by a central computer 28. As shown in Figure 2, each of said machines is connected to the central computer via a communication link 34, 36, 38 in the form of a conventional RS 232 bus.

The transfer crane 18 includes a PLC unit 40 controlled by a central computer 28 which in turn controls the crane to transport the glass sheets to their correct positions in the cutter 2, crusher 4 and grinder 6 so that the latter machines can perform their respective functions on the glass sheets. The PLC unit 40 is also connected to the CNC computers of the cutting, crushing and grinding machines 2, 4, 6 for their functions. . to synchronize.

Transfer crane 8 .. 'In particular, the transfer crane shown in Figures 1 and 3 comprises a pair of rails 42 supported by a plurality of vertical columns 44 β 89350 and extending in a straight line between the cutting machine 2, the crushing machine 4 and the grinding machine 6. The crane 8 includes a carriage 46 moving along rails 42 and a slider 48 supporting a vacuum type handling device 50 provided with a plurality of suction cups 52 (Figure 4) for transporting a glass sheet from one machine to another. The slide 48 moves in the transverse direction of the carriage 46 and the handling device 50 moves vertically with respect to the carriage 46.

Figure 4 schematically shows the overall control of the transfer crane 8. Its PLC unit 40 is connected to a central computer 28 (Fig. 2) via a control panel 54, which allows the crane to be operated manually or automatically. As stated earlier, the PLC unit 40 of the transfer crane 8 is also connected to the computers of the cutting machine 2, the crushing machine 4 and the grinding machine 6 in order to synchronize their functions with the operation of the crane.

The transfer crane PLC unit 40 includes a connection through an electrical housing 56 to the carriage 46 for controlling the position of the carriage along the rails 42 in their longitudinal direction, coupling a slider 48 for the carriage 60 to control its position in the transverse direction of the carriage, and coupling to a handling device 50 for controlling its vertical position. The PLC unit 40 is also connected via an electrical housing 56 to a pneumatic control system 64 for controlling the suction of the suction cups 52 of the processing device 50.

The drive systems 58, 60, 62 of the carriage 46, the slider 48 and the handling device 50, respectively, and the pneumatic system 64, all controlled by the central processor 28 via the PLC 40, may be of known type to control crane operation to sequentially transfer glass blanks GB to cutter 2, crusher 4 and a grinding machine 6, allowing these machines to perform their respective operations on the glass sheet preform before the glass sheet preform is removed from the line by a side crane 12.

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Mower 2

Fig. 5 shows the structure of the cutting machine 2 in more detail, and Fig. 6 schematically shows the control system of the cutting machine. As shown in Fig. 5, the cutting machine 2 includes a pair of rails 66 on each pole of the conveyor belt 67, which conveyor belt receives the glass sheet blanks from the loading aid system. The first carriage 68 moves along the X-axis on rails 66; and the second carriage 70, which is slidable in the grooves 72 of the carriage 68, moves along the Y-axis.

As shown in Figure 6, carriage 68 is driven along the X-axis (along rail 66) by a motor Mx that drives a pair of transfer screws 73 that pass through nuts at opposite ends of the carriage; and the carriage 70 is driven along the Y-axis (transverse to the carriage 68) by a motor My and a transfer screw 74 supported by the carriage 68 and passing through the nut in the carriage 70. Each of these uses further includes an encoder Ex and Ey, respectively, which determine the position of the respective carriage. In addition to the carriage 68, there are two limit switches LSi, LS2, which determine the limit positions of the carriage 70 on the carriage 68.

The carriage 70 carries a cutting head 76, such as a diamond wheel that can be used to cut the outline of glass sheet blanks produced during normal manufacturing, or the process of the device in operation under the control of a CNC computer 78 belonging to the cutting machine 2. The carriage 70 also includes a sensor 80 used to digitize a new outline. .model or drawing, during digitization (or teaching) mode, when a new windscreen shape needs to be entered into the device.

The position of the carriage 70 and thus the positions of the cutting head 76 and the sensor 80 are controlled by the CNC computer 78 via the drive control circuit DCX connected to the motor Mx and the drive control circuit DCy connected to the motor My. The CNC-10 S9350 computer 78 also receives location information of the carriage 70 from encoders Ex, Ey, which provide feedback information to the computer about the actual location of the carriage 70 and thus the actual location of the cutting head 76 and the sensor 80.

The CNC computer 78 further includes a first port for connection to an external communication link 82, e.g., an RS 232 bus, for input of various programs and / or controls? a second port for connection to the control panel 84 for receiving man-machine interface information (MMI), which may be entered, e.g., via a keyboard, joystick, or display screen; and a third port connected to a PLC (prommabale Logic controller) unit 90, which enables the movements of two carriages 68, 70 as well as other functions in the machine to be controlled by a transfer crane 8.

Edge crusher 4

Separation of the glass sheet blank GB from the edge part or crushing of the edge part along the cutting machine 2 cut lines is carried out by heat shocks provided by heating devices, namely gas burners precisely placed at the four corners of the cut glass sheet blank GB. The crushing machine 4 in the apparatus according to Fig. 1 for performing this operation is described in more detail in Figs. 7-9.

As shown in Figs. 7-9, the crushing machine 4 comprises four burners 91-94 each supported by four columns 95 via two horizontal articulated arms 96, 97, the articulated arm 96 is horizontally pivotable relative to the upper end of the vertical column 95 by a motor Ma, and the articulated arm 97 is a horizontally pivotable articulated arm 96 relative to the outer end with a second motor Mb. Each burner 91-94 is supported at the outer end of the respective articulated arm 97.

During the crushing operation, the glass sheet blank GB, into which the desired u 89350 contour is cut by the cutting machine 2, is supported by the suction cups 52 of the transfer crane 8 in the crushing machine on the trough or basin 98. The suction cups adhere to the glass sheet blank inside the cut line. When the torches 91-94 are precisely positioned at the corners of the cut contour pattern, they are made to act to apply a thermal shock to the glass sheet blank GB to separate it from the edge portion along the cut line. The suction cups adhere to the glass sheet blank remaining inside the section line, while the separated outer edge portion falls as crushed into the basin 98.

Fig. 9 schematically shows the control of the crushing operation. The crushing machine includes a CNC computer 100 connected via bus 101 (e.g., RS 232 bus) to a central computer (28, Figure 2). The CNC computer 100 controls the operating circuits 102 of the eight motors Ma, Mb (two for each burner) of the four burners 91-94 so that the burners are precisely positioned relative to the cutting lines of the glass sheet blank. The electrical circuit of the crushing machine 4 illustrated in Fig. 9 further comprises a control panel 104 which enables manual or automatic operation of the machine.

As described in more detail below, each of the four burners 91-94 is placed at one of the four corners of the cut glass sheet blank so that heat is accurately applied to the point of the corner with the smallest radius of curvature. This alignment of the four burners 91-94 is performed automatically under the control of the CNC computer 100 and the central computer 28. When the four burners are precisely aligned, they are ignited under the control of the CNC computer 100 and the PLC unit 106. The heat applied by these four burners to these predetermined points at the four corners of the cut glass sheet GB causes heat to the glass sheet, which nicely separates the cut blank from the remaining edge portion, the edge portion falling as crushed into the basin 98, while the cut portion is a transfer crane 8 transport it to the grinder 6.

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Grinding machine 6

The grinding machine 6 shown in Fig. 1 is shown in more detail in Fig. 10 and its overall control diagram in Fig. 11.

The grinding machine 6 comprises a table 110 for receiving a glass sheet blank GB from the crushing machine 4 transported by a transfer crane 8. The grinding machine further includes a pair of grinding heads 111, 112 (Fig. 11) positioned on opposite sides of the table 110 so as to be contactable with opposite edges of the glass sheet blank when the glass sheet blank is on the table. The table 110 is rotated about the vertical axis of the machine by a motor Mqr »while the two grinding heads 111, 112 are movable longitudinally with respect to the table 112, i.e. perpendicular to the axis of rotation of the table by two motors Mq1, Mq2 so that the outer edges of the glass sheet 110 can be ground and smoothed. Arranging the grinding heads 111, 112 (Fig. 11) on opposite sides of the glass sheet blank allows the grinding operation to be performed simultaneously on two opposite edges of the glass sheet blank, thus substantially reducing the total time required to grind the entire outer edge of the glass sheet blank.

As shown in particular in Fig. 11, the grinding machine 6 comprises a CNC computer 114 which controls the rotation motor Mqr via the drive circuit 116a, and two grinding head motors Mcl »

Mq2 via the other two operating circuits 116b, 116c. The glass sheet blank receiving table 110 is provided with vacuum openings 118 for holding the glass sheet blank firmly on the table during grinding operations. Each grinding head 111, 112 is in the form of a grinding wheel and is supported by a carriage 121, 122, which can be moved by a transfer screw 123, 124 by means of a corresponding motor Mqi, Mq2.

The grinder illustrated in Figure 11 further includes a PLC unit 126 for controlling the functions of the three motors Mqr, Mqi and Mq2, and encoders Egi, Eq2 for providing feedback information to the CNC computer for the operation of the grinding wheels 111 and 112.

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locations.

The CNC computer 114 further includes a port for connection via the RS 232C bus 128 to the central computer 28 (Figure 2) for receiving operating programs, and also for providing a connection link to additional systems. The control panel 130 connected to the CNC computer 114 allows the machine to be operated manually or automatically.

Operating modes (general)

The device shown in the drawings is capable of operating in any of the following modes of operation: (a) Digitization mode, shown in Figure 12a. This mode, sometimes referred to as the training mode, makes it possible to digitize a new contour into the device, according to a model or drawing, to produce a digitizing file 140 representing the contour to be processed by the device. This digitizing file is produced using the optical sensor 80 of the cutting machine 2, to digitize the contour under the supervision of the central computer 28 and also under the supervision of the CNC computer 78 of the cutting machine (Fig. 6). Both the main computer 28 and the CNC computer 78 of the cutting machine 2 include manual data input devices such as a keyboard 30 and display 32 on the central computer 28, and a keyboard 78a and display 78b on the CNC computer 78 that allow manual input of data used to produce the digitization file 140. The operation of the central computer 28 during this digitization mode will be described in more detail below with reference to the flowchart of Fig. 14, and the operation of the CNC computer 78 of the cutting machine 2 will be described in more detail with reference to the flowchart of Fig. 15.

•. (b) The process state shown in Figure 12b. During this mode of operation, the central computer 28 receives a digitization file 140 made during the digitization mode shown in Figure 12a, and also receives data from two other sources, namely: relatively constant data 142 relative to a particular process file to be produced; and manually entered data 144, e.g., identifying a particular file. Data from the three sources 140, 142, 144 are processed in the central computer 28 according to a process program to provide three files, namely: a cutting file CN1 used to control the cutting machine 2; an edge crushing file CN2 used to control the crushing machine 4; and a grinding file CN3 used to control the grinding machine 6.

When producing three files CN1, CN2, CN3, the data for the specified cutting and grinding contour is input by the digitizing file 140, while the relatively constant parameters of the corresponding process are input from the data file 142. Manual input 144 is mainly used to determine the file name.

The operation of the central computer 28 during the process operation mode, for producing the three files CN1, CN2 and CN3, will be described in more detail below with reference to the flowcharts of Figs. 16a, 16b and 16c.

(c) DNC state, shown in Figure 12c. The DNC (Direct Numerical Control) mode is the actual manufacturing operation in which the central computer 28 receives information from the cutting file CN1, the crushing file CN2 and the grinding file CN3, all produced in the process mode shown in Fig. 12b, together with the user / machine interface (MMI), which is manually input via the keyboard 30 and display 32 of the main computer 28 and which controls the cutting machine 2, the crushing machine 4 and the grinding machine 6 via the three RS 232 buses 148, 150, 152, respectively, when the glass sheet blank GB is moved from one machine to the next on a transfer conveyor 8. The three files CN1, CN2 and CN3, produced during the process mode, contain the necessary data and format so that they are available on CNC

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computers in each of the three machines 2, 4 and 6, to control the operation of the corresponding machine in a conventional manner, as is known in CNC-powered systems.

(d) Preprocessing state, shown in Figure 12d. This mode is used to produce a digitizing file corresponding to the digitizing file 140 of Fig. 12 from externally derived data, i.e., data that was not produced during the digitizing operation mode of Fig. 12a described above. For example, this externally derived data may be data obtained from a manual digitization process, pre-existing digitized data, or data obtained from a CAD (computer-aided design) system or a CAM (computer-aided manufacture) system. In such cases, the mainframe 28 receives this externally derived data 154, and also MMI data 156, manually input from the keyboard 30 and display 32 of the mainframe 28, and produces a digitization file, indicated 140 'in Figure 12d, corresponding to the digitizing file 140 in Figure 12a. Thus, the file 140 'can be used in the process mode of Figure 12b to produce three CNC files CN1, CN2 and CN3, to control the cutting machine 2, the crushing machine 4 and the grinding machine 6 during the DNC mode, in the same manner as described above, except that in this case the three files are made from externally derived data, and not from the data derived from the digitization mode of Fig. 12a described above.

(e) Data editing mode, shown in Fig. 12e. This mode is used when making changes to the basic information of any of the above files, e.g., to update the file. During this mode of operation, the central computer 28 receives by means of a data editing program one of the above-mentioned files CN1, CN2, CN3, 140 or 140 ', and also MMI information containing editing data for updating the corresponding file, which MMI information is manually entered on the CPU 28 keyboard and display 32. through.

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The above-mentioned operating modes are implemented by equipping the central computer 28 or the CNC computer in the respective cutting machine 2, crushing machine 4 and grinding machine 6, with a suitable program, as described below.

Coordinate system

Figure 13 shows the coordinate system on which all machine functions are based.

Thus, the cutting machine 2 includes a reference center, which is marked "01" in Fig. 13, and which is the reference center of the machine. Ts. all dimensions related to the operations to be performed by the cutting machine are shown in the X-direction and in the Y-direction with respect to this reference center "01".

On the other hand, the cutting machine 2 as well as the crushing machine 4 and the grinding machine 6 each have a theoretical center marked "MC" (machine center) in Fig. 13. The glass sheet blank GB has a corresponding reference center MC. When the transfer conveyor 8 conveys the glass sheet GB from one machine to the next, it places the center MC of the glass sheet GB at the center MC of the corresponding machine. All command instructions are then given in relation to the distance between the center MC of the glass plate and the reference center "01" of the machine along the X-axis (dimension "XC" in Fig. 13) and along the Y-axis (dimension "YC").

In Fig. 13, the GB dimensions of the glass sheet blank are marked "XGLASS" along the X-axis, and "YGLASS" along the Y-axis; while the maximum dimensions of the contour to be cut on the glass plate are marked "XL" along the X-axis and "YL" along the "Y" axis.

Implementation of diquitation mode

As briefly described above, the digitizing mode (also called the teaching mode) illustrated in Figure 12a utilizes the cutting machine 2, and in particular its optical sensor 80, to digitize a new outline from a model or drawing to produce a digitizing file 140 representing the outline to be processed by the device; this digitizing file is used during the next process mode (Fig. 12b) to produce three CNC files CN1, CN2, CN3, which are used in the DNC mode (i.e. production) to control the cutting machine 2, the crushing machine 4 and the grinding machine 6. Fig. 14 is a flowchart illustrating the main computer 22 programmed functions during the digitizing mode, while the flowchart of Fig. 15 illustrates the programmed functions of the CNC computer 78 (Fig. 6) for controlling the cutting machine during the digitizing mode.

As shown in the flowchart of Figure 14, the host computer 28 requests data from the CNC computer 78, including the file name and coordinate point data, which data is transmitted to the host computer 28 from the CNC computer 78 via the bus 82 (Figure 6). The central computer 28 performs a check on the content of this information by a conventional checksum procedure, and also asks, after receiving all the data bits, whether this is an end character.

If not, it continues to receive the data and stores it in the digitalization file DF. When the end signal is received, the digitizing operation is stopped.

The program of the CNC computer 78 (Fig. 6) during the digitizing mode is somewhat more complex, as shown in Fig. 15. This program includes a parameter called "LD", which represents the maximum distance from one sampling point to the next during the digitizing operation. The program includes two interrelated parameters, namely DLD, which represents the distance to be deducted from the distance LD during program operation, and LD ^, which represents the minimum distance LD. As one example, the LD may be 30 mm, the DLD may be 5 mm, and the LD 1 may be 1 mm.

The flowchart shown in Fig. 15 for controlling the CNC computer 78 during the digitizing mode comprises a second parameter named "a", and an associated parameter "« max "· The meaning of this parameter and its relationship to the distance" LD "is shown in more detail in the diagram of Fig. 15a. illustrates the digitizing state applied to three consecutive points, namely point "nl", point "n" and point "n + 1", along which the contour is digitized.

Referring to the flowchart of Fig. 15, the CNC computer 78 (Fig. 6) of the cutting machine 2 takes a sample of the first point (n1, Fig. 15a) during the digitizing mode, and transmits the value of this point to the main computer 28. The CNC computer 78 then performs a step travel along the LD axis and then take a sample from the next point (n, Fig. 15a) and transfer this value to the main computer 28. The CNC computer 78 then takes a sample from the third point (n + 1, Fig. 15a) and calculates the angle "a" between the points "n" and "n +1 "between the line and the extension of the line between points" nl "and" n ". If this angle "a" is less than the specified "α ^ χ", the computer transfers the data of the point "n + 1" to the CNC computer 78 and proceeds to the next sampling point of the distance "LD" from the point "n + 1". However, if "a" is greater than the specified "α ^ χ", the computer returns to the previous point "n", checks if "LD" is greater than the specified LD ^ in, and if so, subtracts the distance "DLD" from the distance LD and then returns to the new point LD minus the original distance LD on the path DLD. On the other hand, if the distance "LD" is less than the specified LD ^ in »the program accepts this data and transfers this point to the main computer 28 for attachment to the digitization file, then adds the distance DLD to the distance LD, and checks if this is the last point. If not, the program proceeds to the next point where the above procedure is repeated for that point. When the last point is completed, the program is completed.

As can be seen, the operating program of the CNC computer 78 of the cutting machine 2, illustrated by the flow chart of Fig. 15, causes the sensor 80 (Fig. 6) to operate during the digitization mode.

To feel the contour of a drawing or drawing at relatively long distances LD (e.g., 30 mm) where the contour has a relatively large radius of curvature indicated by a relatively small angle "a". However, where the radius of curvature is relatively small, indicated by the angle "a" being greater than "aj4Ax" f, the maximum distance LD (e.g.

30 mm) at a given distance DLD (eg 5 mm) in one or more successive steps until the measured angle "a" is less than "α ^ χ" in order to obtain sampling points closer to each other at those points of the contour with a relatively small radius of curvature. However, as soon as this sampling distance LD has decreased below the specified minimum LDmin (e.g. 1 mm), no further reduction is made to the sample distance and the measurement is taken from that point and transferred to the central computer 28 for attachment to the digitization file.

The parameters LD, DLD, and LD ^ in, as well as α ^ χ (e.g., 4 °), are included in the standard parameter file 79 entered into the CNC computer 78 (Fig. 12a) during the digitization mode. These parameters are relatively constant for each windshield model being manufactured, but can be changed as needed.

Executing process mode

As previously described in connection with the process mode shown in Figure 12b, the host computer 28 receives a digitization file 140 made during the digitization mode of Figure 12a, as well as other data file 142 and manually entered data 144, and prepares three CNC files, CNCl, CNC2, CNC3 for use in CNC for controlling computers in a cutting machine 2, a crushing machine 4 and a grinding machine 6 during the DNC mode of operation (manufacture) of the system. Figures 16a, 16b, 16c together show a flow chart of a program of the central computer 28 for performing this process mode of operation.

As shown in Figure 16a, the system first reads the file name from the manually entered data 144 and then reads the process data from the data file 142 and the digitizing data from the digitization file 140. The process data from the data file 142 contains all relatively constant values for the corresponding process, e.g. YC (Fig. 13) on each machine with respect to the machine center MC of the glass sheet blank GB; the starting points of the carriage 70 of the cutting machine 2, the starting points of the burners 91-94 of the crushing machine 4, and the starting points of the grinding wheels 111, 112 of the grinding machine 6; the starting angles 96 of each of the articulated arms 96, 97 of the crushing machine 4; the start-up time of the burners 91-94 of the crushing machine 4; the diameter of the hi-discs 111, 112; the maximum accelerations and speeds allowed for the movements of the different elements of the three machines, etc. As previously mentioned, the data in file 142 is relatively constant, but can be changed or updated whenever necessary using the data editing mode shown in Figure 12e.

As shown in the flowchart of Fig. 16a, the computer first begins performing processing for the cutting machine to produce the cutting machine file CN1.

Initially, the computer performs the necessary kinematic calculations to determine if it is within certain allowable boundary conditions, as defined in data file 142. One boundary condition is the maximum allowable speed for each axis; e.g.

40 meters per minute. The computer also calculates the maximum acceleration (or deceleration) when changing speeds to determine if this is also within the allowable limits, as excessive acceleration (or deceleration) can overload the drive or cause a mechanical failure of the system. If the maximum speed or acceleration is exceeded, the system rejects that point, reduces the speed, and then performs new kinematic calculations until the speed and acceleration as well as the processing limits are exceeded.

The above kinematic calculations are well known in CNC machines, which is why the details of such a procedure are not presented here.

Once all the points have been determined within the allowable boundary conditions, the information is input to the CN1 file for use in controlling the cutting machine 2. The computer then proceeds to process the data to produce a CNC file CN2 for controlling the crusher 4.

As shown in the flowchart of Fig. 16b, to produce the crushing machine file CN2, the computer first searches the four corners of the contour defined by the digitizing file by locating the minimum point of the radius of curvature in each of the four quarters of the cut glass sheet GB. This information, which identifies the locations of the smallest radius of curvature at the four corners of the outlined glass sheet, is converted to the angle A1 of the articulated arm 96 (Fig. 8) relative to its column 95 and the angle A12 of the articulated arm 97 to the articulated arm 96 for each of the four burners 91-94; this places the corresponding burner exactly at the minimum point of the radius of curvature in the glass sheet blank GB at a corresponding angle to the incision.

Since the lengths of the articulated arms 96 and 97 are known for each of the four burners 91-94, and since the minimum point of the radius of curvature is determined for each burner, simple mathematical calculations can be used to determine the angles A1 and A12 to accurately position the respective burner at this minimum radius of curvature. The controls Ma and Mb of the two motors of each burner 91-94, to position the respective burner according to exactly the calculated angles, are transferred to the CNC file CN2 for use in controlling the crushing machine during the crushing operation. The computer then proceeds to prepare a CNC file to control the CN3 grinder 6.

The first step in producing the grinding file CN3 is to locate the location of each grinding wheel 111, 112 (Fig. 11) for each grinding point on the outer surface of the finished contour of the glass sheet blank GB. In Fig. 17, the contour points of the finished glass blank S9350 GB are marked with points Pi ---- Pn; and the respective centers of the grinding wheels 111 and 112 corresponding to these points are denoted ---- Gn.

When determining the grinding centers Gi ---- Gn, a line "R" is drawn from its corresponding point on the glass plate P 1 perpendicular to the line between its point and the previous point, the distance (R) corresponding to the point in question. the radius of the grinding wheel 111, 112.

Each of the grinding centers Gi ---- Gn is determined by polar coordinates. For this purpose, a line (X1 for Gi) is drawn from the machine center MC of the glass sheet blank GB to the corresponding point Gi so that the point Gi is determined with respect to the machine center MC by the length of the line (X1) and the angle between that line and the horizontal line passing through the machine center MC ).

Next, a table is prepared defining the positions of the two grinding heads 111, 112 for each angle (Θ) around the periphery of the contour of the finished glass sheet blank. Since the glass sheet blank is ground simultaneously with two grinding wheels 111, 112 on opposite sides of the glass sheet blank, a table is made for rotating the glass sheet blank only 180 °, as follows:

First, the table is made for angles 0 and distances X for a full 360 ° according to the following table A:

Table A

0 ° X

10 100 100 150 150 140 200 120 250 110 300 150 350 170 23 8 9 3 5 0

Table Βχ is then prepared by displaying the values of X for an angle (Θ) of 0 to 180 °, and Table B2 is prepared by displaying the values of Y for angles 181 to 360 ° after subtracting 180 °, both as shown below:

Table Bi Table B?

θ ° X 0 ° Y

10 100 200-180 = 20 120 100 150 250-180 = 70 110 150 140 300-180 = 120 150 360-180 = 180 170

The new Table C is then prepared by combining Tables B1 and B2 as shown below:

Table C

0 ° X Y

10 100 20 120 70 110 100 150 120 150 150 140 180 170

Although each of the above tables contains only some values, it is to be understood that these are presented for illustrative purposes only and that each table contains a significantly larger number of values. For example, Tables A and C may each contain about 400 values, dividing the perimeter of the glass sheet blank into 400 points, each deviating from the next by less than 1 °. The distances between the points can be filled by interpolation.

It is observed that Table C defines two grinding wheels 111,

24 b 9 3 5 O

112 stations during grinding operations, in which case the grinding wheels contact the glass sheet blank over the entire 360 ° circumference, even if the glass sheet sander is rotated only 180 °.

Once the positions of the grinding wheels have thus been determined, the kinematic calculations described above in connection with the preparation of the CN1 file are also performed to ensure that the maximum speed and acceleration limits are not exceeded. If any point exceeds one of these limits, the point is changed until the limit is exceeded.

Once all the points for controlling its grinding wheels 111, 112 have thus been determined, these points are printed in a file CN3 which is used to control the grinding machine 6 during grinding.

When this procedure is completed, the process operation mode described in Figs. 16a to 16c is terminated.

The three files CN1, CN2, CN3 produced during the process operation mode shown in Figs. 16a to 16c can then be used during the production DNC to control the operation of the cutting machine 2, the crushing machine 4 and the grinding machine 6 via the central computer 28. During this DNC mode, the mainframe 28 is also provided with MMI information, as shown at 146 in Figure 12c, which information is manually entered via the mainframe keyboard 30 and display 32.

The preprocessing mode illustrated in Fig. 12d used to produce a digital file corresponding to the citation file 140 from the externally derived data in Fig. 12a and not from the data digitized by the cutter 2 during the digitizing operation mode can be used in the same manner as described above for the digitizing operation mode shown in Fig. 12a. externally derived data. In addition, the data editing mode described in Fig. 12e, which is used to make changes to the basic information of any of the above files (e.g., file update 25 S9350), is controlled by the central computer 28 in a conventional manner as shown in Fig. 12e to update old data in file 160. in Fig. 12e, with editing data 162 manually input to the central computer 28 to provide the modified data file 160 '.

The mainframe computer 28 may be one of many commercial personal computers, e.g., an IBM PC; and each of the CNC computers used in the three machines 2, 4, 6 (e.g., the CNC computer 78 in the cutting machine 2 of Fig. 6) may be a FANUC 11.

The invention has been described above with reference to one preferred embodiment, it is to be understood that many other modifications and applications may be made to the invention.

For example, the transfer crane illustrated in Figures 1 and 3 may comprise two or preferably three spaced carriages 46, all of which are mechanically connected together to move together. The distance between the slides is the same as the distance between the centers of the cutting, crushing and grinding machines 2, 4 and 6. In this embodiment, the rails 42 can be extended so that one of said two or three carriages 46 replaces the side crane 12. In this case, the cutting, crushing and grinding machines 2, 4 and 6 are equidistant from each other.

Claims (3)

26: 9350 Pat ent1i v aa t imuk set A method for cutting 1 blank blanks according to a predetermined contour, the method automatically transporting 1 blank (GE) to a cutting machine (2), then to an edge crushing machine (4) and then to an edge grinding machine (6); and using digital control files to control the cutting machine (2) to cut the desired contour of the glass blank, to control the crushing machine (4) to separate the cut edge portion from the glass sheet blank, and to control the grinder from smoothing the edges of the separated glass blank, characterized by a digital cutting file (CN1) and a digital grinding file (CN3) on a computer (28), and that the cutting machine (2) and its various uses (Mx, My) are controlled by said digital cutting file (CN1) and a grinding machine (6) comprising two the grinding head with its drive motors (MG 1, MG2) is controlled by said digital grinding file (CN3) so that both grinding heads of the grinding machine (6) simultaneously grind opposite edges of one glass plate. 2. Anordering the glass glazing after the best of the contours, for example the glazing of the glazing (2) for the glazing and gating in the contour; in the case of a cross-country mask (4) for the glazing of the glazing of the gate, in addition to the glazing of the gate (6) for the glazing of the gate, for use with respect to the sliding, sliding and octagonal operation, colors to the slip mask (6) to the border (110) for the glass sliding, turning the slope, to the slipper (6 slots) (111, 112) , as well as the slip-on velvet slip of the slip-on edge of the glass, anslut.it s med en över f ör i ngs 1 yf tkran (8) av gl asskivämnena account samma produktionslinje som skärmaskinen (2) och kantkrossnings- I; 29 b 9 3 50 masquerade (4) complete with image of the machine tool in the form of a digital signal filter (CN1, CN2, CN3), a single image of the digital digital contour1 (140) some repressors of this contour-1. An apparatus 1 for cutting sheet metal blanks according to a predetermined contour, the apparatus comprising a cutting machine (2) for cutting the outline vii1 of a glass sheet blank; an edge crusher (4) for separating the edge portion outside the outwardly curved outline from the glass sheet blank, a grinding machine (6) for smoothing the edges of the separated sheet blank, and a conveyor (8) for the grinding machine (6) comprising a table (110) for supporting the plate blank, characterized in that the grinding machine (6) provided with two grinding heads (111, 112), both grinding heads simultaneously grinding opposite edges of one glass sheet, is connected to a sheet blade production crane 11a (8) li 27 89350 with the cutting machine (2) and the edge crushing machine (4) and that the different drives of each of the three machines are arranged to be controlled by three different digital control files (CN1, CN2, CN3) formed from the same digital outline file (140) representing said outline. Device according to claim 2, characterized in that the device comprises in combination - an apparatus for digitizing said contour, comprising an outline sensor (80) for sensing the contour of the pattern or drawing of the cut sheet by ethnic point, the density of points increasing as the degree of contour curvature increases; - means (28) controlled by said contour sensor (80) for producing said digital contour file (140); - a control system (28; 78, 90; 114, 126) comprising at least one computer (78, 114) programmed to use said digital contour file (140), a digital edge crushing file (CN2) and a digital grinding file (CN3) ); - two grinding heads (111, 112) in said grinding machine (6) on opposite sides of said table (110) and a drive motor (MG1, MG2) for each grinding head, said control system (28, 114, 126) controlling by means of a digital grinding file (CN3) movements of the two grinding heads (111, 112) so that the grinding heads simultaneously grind opposite edges of the cut glass sheet blank according to a digital grinding file (CN3); and - a separate drive (M *, My) belonging to the cutting machine (2) for cutting the contour of the glass sheet blank, said control system (28, 78, 90) controlling the movements of the drive (Mx, My) by means of a digital cutting file (CN1) ). 28 ϋ9350 P a tentkrav] .. Förfarande färra glasskivämnen efter en besturd konturlinje, i vilket förfarande glasskivämnet (GB) automatic conveyor to the wheel (2), sedan to en kantkross-masin (4) and sedan till en kantslip ); and digital styrofoils are attached to the styrofoam (2) of the glass stitches are self-contained contours, for the styrofoam (4) kanter, kännetecknat av, att av den en bestämd konturlinje representerand digitala konturlinje-filen (140) medelst en dator (28) framställas en digital skär-fil (CN1) och en digital slipfil (CN3), och att skärmaskinen (2) och dess separatdrift (Mx, My) styres med nämnda digitala skärfil (CN1) ocl slipmaskinen (6), omfattande tvä sliphuvuden jämte drivmotorer (MG1, MG2), styres med nämnda digitala slipfil (CN3) sä att siipmaskinens (6) kanter av en glasskiva. 3. An arrangement according to claim 2, comprising a combination of an arrangement and a combination of a contour line with a contour line (80) for the contour of the model according to which the circle is connected to a glass point at a point such as in the context of the contour line; - an organ styrda (28) with said contour1 injector (80) for framing 11 and a digital contour1 injector (140); - that the system (28; 78, 90; 114, 126) is equipped with a memory and a computer (78, 114) programmed to provide a digital circuit (140) for digital transmission (CN1) and digital crossover (CN2) and en digital siipfi1 (CN3); - a slip huvuden (111, 114) in said slip mask (6) head mot-satta sidor om nämnda bord (110) och en drivmotor (MG1, MG2) for a forward slip huvudet, varvid nämnda styrsystem (28, 114, 126) med hjälp av the digital slip file (CN3) is connected to the digital slip file (111, 112), the slip data being the same as the slider of the glass glaze of the digital slip file (CN3); och - en till skärmaskinen (2) a separate drive line (Mx, My) for a line and a glass circuit, colors of these styrene systems (28, 78, 90) with a digital drive line (CN1) stating the drive line (Mx, My and enlarge with the digital screen (CN1).