DE1154180B - Program control for bending machines - Google Patents

Description

Program control for bending machines The invention relates to a program control for bending machines, especially pipe cold bending machines. With pipe cold bending machines up to twelve angles are bent one after the other, whereby Certain rotations can still be made between the individual angles. It it is known to use bending and twisting angles in such bending machines of so-called cam disks that interact with limit switches. The cam disks are mounted on a common axis and make the movements the machine with. Because the individual cam disks in a very specific order are approached, they must be set in a very specific sequence according to the program will. This has the disadvantage that practically every program change Cam disks have to be readjusted and adjusted. Further must for everyone following bending angle a cam disc may be provided, even if in the course of the The same bending angle must be carried out in the program. With the known program controls all the cam disks have to be readjusted and adjusted if the desired degrees of bending are available, but not in the desired order Are available.

According to the invention, in a program control for bending machines, in which the individual bending and / or twisting angles with the help of on cam disks arranged switching cams are adjustable, a significant improvement can be achieved that the individual cam disks in an arbitrary order with Help from the selector switches assigned to the program steps can be selected, with each cam disc can be selected several times in the program sequence in any order can. In this way it is possible to use the same number of cam disks to carry out a much more extensive program. As also for repeated occurrences same bending angle only a single cam disc needs to be adjusted, can not only make a more precise bend, but also significantly shorten the length of the bend Set-up time can be achieved. It is also possible to simultaneously measure the angular degrees to save for several pipe types.

The invention is described below in connection with the drawing.

Fig. 1 shows in principle the mechanical part of the program control, only the parts of the bending machine that are essential for understanding the invention are shown; Figs. 2 to 4 give the electrical part of the program control again.

With the bending machine indicated in FIG. 1, up to twelve bending angles and up to eleven angles of rotation are to be executed. The control is designed in a corresponding manner. 1 with the tubular workpiece is referred to, which is pressed with the aid of a clamping jaw 2 on the bending head 3 of the bending machine; which can be rotated with a shaft 4 to perform the bending movement. The bending drive, which is controlled with the aid of solenoid valves, is connected to the shaft 4 in a manner known per se. A shaft 6, on which twelve cam disks n 1 to n12 can be continuously adjusted to specific angular degrees, is driven via an angular gear 5. For example, a disk 7 with graduation or the like can be used for setting. The cam disks h1. to n12, EnC holders e1 to e12 are assigned, which are fastened in a strip 8. Microswitches which have a relatively short switching path are preferably used as limit switches e1 to e12. They are preferably designed as changeover switches, as will be explained in more detail with reference to FIGS. 2 to 4. When the limit switch is actuated by the corresponding switching cams, the bending drive is switched off and the work processes following the bending movement are initiated.

The tube 1 to be bent is in a clamping head 9 of the bending machine clamped. The cam disks n1 'to n12' sit on the clamping head, with their The respective angle of rotation is adjustable with the help of this. With the cam disks n1 'to n12 ', limit switches e 1' to e12 'work together, which are located in an end switch strip 10 arranged and like the limit switches e 1 to e12 for the bending angle are trained. The cam disks n1 'to n12' can also be separated from the machine be arranged. A transmission or, for example, can be used as the transmission of movement serve an electric wave.

2 shows the circuit diagram for the preselection of the limit switches e 1 to e 12 or e 1 'to e 1.2' which interact with the cam disks n1 to n12 or n 1 ' to n 12'. The bending angle is preselected with the selector switches W 1 to W12, the contacts of which are connected to the limit switches e 1 to e12, so that the limit switches e1 to e12 can be preselected in any order. The selector switches W 1 'to W12' are provided for setting the angle of rotation, with the aid of which the limit switches e1 'to e12' can be selected, also in any order. With the help of the switch u1 'to u12'. In addition, it can be determined whether the angle of rotation is to be executed by turning it to the left or to the right. As can be seen, a selector switch W 1 or W 1 'to W 12 or W12' is assigned to each program step. The program steps are triggered by a stepping mechanism or a relay chain (Fig. 4). Under certain circumstances it can be expedient for a specific twist angle to be assigned to each bending angle and vice versa. In this case, the axes of the selector switch W and the axes of the corresponding selector switch W 'are mechanically coupled to one another.

MVB indicates the connection of a solenoid valve for bending, d. This means that the bending drive is activated. In a corresponding way are the connections for the solenoid valves for clockwise and counter-clockwise rotation with MVDr and MVDI.

It is quite obvious that in a bending machine, besides the bending process and the twisting process, other movement processes take place - which must be taken into account in the automation of the bending machine, such as tube loading, tube transport, piston clamping, mandrel movement, bending table movement and the like. m. The switching means and circuits required for this are only entered in the drawing as far as is necessary to understand the overall context. In the right part of Fig. 3, therefore, only the relays D 4 (pipe clamping), D 5 (bending) and D 12 (twisting) are entered, while the relays D 6 to D 12 for the movements in between are not shown. The automatic sequence is ensured by sequential switching of the relays mentioned. Since remanence relays are preferably used as relays, a discharge line 11 and two switching lines 12 and 13 are provided; the latter are alternately connected to voltage through contacts d31 and d32 of a relay D3.

4 shows the chain for the program steps constructed with remanence relays D 15 to D 26 , the number of switching steps being able to be preselected with the aid of a step switch St. D 13 designates a contactor which, after the set switching steps have elapsed, causes the pipe bending machine to be switched off or the last operation to be triggered (pipe ejection). The lower row of contacts of the switch St is connected to the corresponding remanence relays D 16 to D 26. This enables the chain to return to its starting position after the number of steps has been completed. In Fig. 4, the two discharge lines for the remanence contactor chain are denoted .mit 15 and 16, while the common discharge line is denoted by 17.

The program control works as follows: First of all, all required bending angles are set on the cam disks n1 to n12. In the same way, the cam disks n 1 ' to n 12' are also set for the required angle of rotation. The order in which they are set is completely irrelevant here, since all of the cam disks can be selected in any order with the aid of the selector switches W 1 to W12 or W 1 'to W12'. Once all the required angles have been set, the sequence of the angles can now be determined with the aid of the selector switches W 1 to W 12 or W 1 'to W 12'. For example, the selector switch W 1 is set to contact 2, which is connected to the limit switch contact e 2, which in turn is assigned to the cam disk n2. The selector switch W2 is set to contact 1 and the selector switch W 3 to contact 6. Once the bending and twisting angles have been set, the actual bending process can begin. To do this, the terminals marked "On" must be bridged. This can be done either by hand using a push button or with a certain previously required function of the machine. Since these terminals are connected to the starting lines 12 and 13, the contactor D 4 receives a switch-on pulse. The so-called "pipe clamping" is initiated by this contactor, namely the clamping jaw 2 is pressed against the bending head 3. In addition, by closing contacts d41 to d43, the response line of the following contactor D 5 is prepared for bending, its own discharge line and the response line for contactor D 3. After the pipe has been tensioned, the corresponding limit switch is actuated so that contactor D 3 now receives voltage. Thereby, the contact is opened and the contact d31 d32 When shut, so that now the bending contactor D prepared through the contact d41 5 receives voltage. As a result, the circuit of the next contactor D 6, which is not shown in the drawing, is prepared and the contactor D 4 is thrown off, since it is now connected to the discharge line 11 via the contacts d 42 and d 53. By closing the contact d51 (Fig. 2) of the contactor D 5 , the solenoid valve MVB also receives voltage via the preselected limit switch contact e2 and via the contact d15. The contact d15 is assigned to the relay D15 (FIG. 4), which has received voltage when a contact d 143 of a relay D 14 is closed. Now the actual bending process begins and is only ended when the limit switch e2 is actuated by the cam disk n2 , which interrupts the circuit of the solenoid valve MVB and then applies voltage to a relay D 1. At the end of the bending process, the machine actuates the button eb, so that the contactor D 3 is now switched off via the contact d 53 of the bending protection D 5. When contactor D 3 drops out, contact d32 is opened and contact d31 is closed. As a result, the next contactor D 6 is switched on, which now triggers a further movement process of the bending machine, but this is not shown in the drawing. In the course of the movement process, the sequence switch ef is finally actuated, which applies voltage to the contactor D 3 (FIG. 3) via the contact d 112 of the contactor D 11, not shown in the drawing. By closing contact d111, contactor D 12 receives voltage and picks up. This contactor initiates the angular rotation. Via contact d121 of this contactor, changeover contact u l ', limit switch contact el' and selector switch contact e1 ', the solenoid valve MVDr receives voltage for turning to the right. At the end of the angle of rotation, a limit switch contact ev is closed, which causes contactor D 3 to drop out. As the contactor D 3 drops out, the contactor D 4 for the tube tensioning of the chain D 4 to D12 is now again connected to voltage as the next contactor, so that the movement process begins again from the beginning for the next bending angle. At the same time, contactor D 15 is switched off and the next contactor D 16 in the chain is switched on. By closing the associated contacts d 16 and d 16 ', the circuits of the selector switch W 2 or W2' for the next bending or. Twist angle prepared.

Claims (2)

PATENT CLAIMS: 1. Program control for bending machines, in particular Pipe cold bending machines in which the bending and / or twisting angle is determined using Switching cams arranged on cam disks are adjustable, characterized in that that the individual cam disks in an arbitrary order with the help of the Selector switches assigned to program steps can be selected, with each cam disk can be selected several times in the program sequence in any order. 2. Program control according to claim 1, characterized in that the number of program steps with the help Another selector switch is preselectable, which after the program has run the Shutdown of the machine initiated directly or indirectly. Considered Publications: German utility models No. 1734 033, 1734 462; French patent specification No. 1192 511.