EP1230048A1

EP1230048A1 - Method for producing casting molds

Info

Publication number: EP1230048A1
Application number: EP00987075A
Authority: EP
Inventors: Mohammed Ali Seiraffi; Holger Schreiber; Jürgen RETTIG
Original assignee: Adolf Hottinger Maschinenbau GmbH
Current assignee: Adolf Hottinger Maschinenbau GmbH
Priority date: 1999-11-18
Filing date: 2000-11-03
Publication date: 2002-08-14
Also published as: CA2386369A1; US20030051856A1; WO2001036129A1

Abstract

The invention relates to a method for producing casting molds, especially comprised of cores or core packages, whereby molding materials, preferably molding sands, are blown or shot into a molding chamber via a gaseous flow medium, preferably via air, and under a pressure that can be predefined. The shot and resulting solidified mold is then evacuated of air, and the form is opened, upon which the shot mold is subsequently removed. The invention is characterized in that the shooting process and/or the air evacuation process is/are controlled using detected and optionally prepared process parameters according to any predefined specification.

Description

"Process for the production of molds"

The invention relates to a process for the production of casting molds, in particular consisting of cores or core packages, molding materials, preferably molding sands, being blown or shot into a molding chamber under a predetermined pressure via a gaseous flow medium, preferably via air, the shot and thereby solidified mold vented, the tool opened and after the tool is opened the closed mold is removed.

The invention relates generally to the field of foundry technology. For the casting of shaped pieces of any kind, foundry cores or molds are usually produced in separate parts, brought together and connected to one another to form a casting mold or a core package. These core packages are then filled with molten metal to produce, for example, a metallic workpiece, the series of core packages to be filled with molten metal passing through the production line in succession.

Core and mask shooting machines of the aforementioned type have been known in practice for decades. For example only, reference is made to DE 31 48 461 C1, which discloses a core and mask shooting machine.

So far, the production of ready-to-cast masks or core packages has been carried out from a control device or a control panel, with a fixed control being specified for the production. In the event of a change in the production sequence or in the event of a change in individual production steps or production stations, it was necessary to change or adapt the control. Automatic monitoring or even regulation of the manufacturing process, in particular the actual shooting process, through the ventilation up to the removal of the shot core, has not taken place.

Now, when casting molds, on the one hand during the actual shooting process and on the other hand when venting and then opening the mold, very considerable problems can occur which counteract an optimization of the manufacturing process. For example, individual shot nozzles and / or Add ventilation nozzles with core sand, so that there is necessarily a longer process time or an insufficient result of the manufacturing process. Tool wear or damage to the tool also counteract an optimal production result. Too rapid venting of the shooting hood after the shooting process would cause the sand to swirl or flow back, which on the one hand negatively affects the production result and on the other hand the production quality, but especially the cycle time.

From DE 44 22 353 C2 a method for the production of casting molds or parts of such molds is already known, the blowing-in or firing process being terminated there at a time which is a function of the pressure in the molding chamber. Specifically, the blowing process is ended when the pressure in the molding chamber has passed a maximum. The maximum of the pressure is therefore an indicator of the end of the blowing process. No other parameters are included here.

The method known from DE 44 22 353 C2 is problematic in practice, however, since only a maximum pressure is detected. If, for example, a pressure maximum arises when the nozzles become increasingly clogged, the blowing process is ended without an adequate shaping being able to take place. Ultimately, the known method is a control, the parameter used for the control being the pressure maximum within the molding chamber.

The present invention is based on the object of developing a method of the generic type in such a way that process monitoring for quality assurance takes place with simple means.

The method according to the invention achieves the above object by the features of patent claim 1. The generic method is characterized in that the firing process and / or the venting process is regulated by means of detected and optionally processed process parameters according to any predetermined specification. In contrast to the generic state of the art, there is no control when a maximum pressure is detected, rather, a regulation is carried out, which is based on process parameters according to any prescribable regulation. In any case, the processes of actual firing and venting before the shot and solidified form are removed are affected. The aim of such a regulation is to reduce the cycle time, to automate the manufacturing process and to identify defects or errors via conclusions from the process parameters and the resulting cycle times.

In concrete terms, the control could be based on individual process parameters, predefinable combinations of the process parameters or algorithms based on the process parameters. Furthermore, for the respective process section or process, i.e. for the actual shooting and / or for venting, a maximum process duration can be specified as special process parameters. If a longer process time resulted or were calculated based on the other process parameters, conclusions could be drawn about a defect, for example clogged nozzles, defects on the tool or the like. In the end, it is the detected parameters that allow different conclusions to be drawn about the quality of the production and / or the condition of the tool.

At this point it should be particularly emphasized that the process parameter that can be detected is the pressure that builds up in the overall system during firing or that prevails there. Specifically, this can be the pressure in the shot air reservoir, in the sand bunker, in the tool, in the pipes or anywhere else in the system. In contrast to a control when a predetermined or predeterminable maximum pressure is reached, a pressure curve could be used as a basis here when the shooting process was carried out correctly, with which the actual pressure curve across the shooting process is compared. If the actual pressure curve deviates from the specified pressure curve, the duration of the shooting process could be lengthened or shortened by a corresponding regulation, depending on the type and the amount of the deviation.

As an alternative or in addition to the detection of the pressure or the pressure curve, the volume flow could be used as a further process parameter during firing or the air flow in the overall system, for example in the tool, can be detected. Here, too, a course of the volume flow or the air flow extending over the shooting process could be used as the target specification, so that in the event of a deviation from the target values, intervention is made, which ultimately affects the course of time and / or the required Pressure affects. Increasing blockage of the shot nozzles could be counteracted at least to a certain extent by increasing the pressure.

It is also conceivable to detect the amount of sand blown into the tool as a process parameter, this being possible for example via the weight loss in the storage container or via the weight increase in the tool or in the molding chamber. The firing process could be ended on the basis of several process parameters, taking into account the specific course of the process parameters across the manufacturing process.

It is also conceivable to regulate the course of the venting process and, if appropriate, the point in time at which the tool is opened via detected and optionally processed process parameters, in a manner similar to that in the case of the actual firing process. During the venting of the tool, the pressure curve within the tool could be detected as a process parameter and a comparison could take place with a predetermined pressure curve with ideal ventilation.

Furthermore, it is possible to detect the air flow, in particular the amount of air flowing out of the tool, as process parameters during the venting of the tool. As soon as a predeterminable amount of air has escaped, the tool could be opened, depending on the internal volume of the tool.

In the context of a very particularly advantageous embodiment of the method according to the invention, when the tool is vented, a preferably electromagnetic venting valve is controlled in such a way that the pressure prevailing in the tool drops - gradually - while avoiding pressure jumps. A linear pressure drop has proven to be particularly advantageous in order to To avoid sand particles being carried along to the vent valve or backwards into the shot nozzles. Blockages caused by entrained sand particles should be effectively avoided here.

Furthermore, the individual production steps or processes and / or the detected and / or ascertained process parameters could preferably be compared with an optimal curve of the process course via a graphic that can be shown on a display. Within the scope of such an embodiment, an optical comparison can be made on the basis of two curves, the operator being able to intervene interactively - regulatingly - when the curves deviate, namely on the basis of the comparison or any deviations. An automatic adjustment in the event of corresponding deviations is also conceivable, such an adjustment having a regular effect on the time course of the process.

As already mentioned above, the - ideal - process duration could be determined on the basis of the detected and / or determined process parameters, the aim being to minimize the cycle time. For example, one could stipulate that maintenance should be carried out or that the tool be replaced when a predefined cycle time is exceeded.

In any case, it is fundamentally conceivable that, based on the detected and / or determined process parameters, the respective process is monitored with regard to any errors or defects on the tool or on the machine itself. Ultimately, it is possible to draw conclusions about the quality of the production and / or the condition of the tool or the machine from the determined and possibly processed process parameters. On the basis of the detected and / or determined parameters, for example, the ideal time for an automatic tool change can also be defined, so that the shortest possible cycle time can be achieved with a tool that is always correct. The - optimal - maintenance interval can also be calculated on the basis of the detected and / or determined process parameters, so that the cycle time can be minimized, but above all the unnecessary repair work can be minimized due to proper and adequate maintenance. Finally, it should be particularly pointed out that the above discussion of the claimed teaching does not restrict it beyond the claims.

Claims

Patent claims

1. A process for the production of casting molds, in particular consisting of cores or core packages, molding materials, preferably molding sands, being blown or shot into a molding chamber under a prescribable pressure via a gaseous flow medium, preferably via air, the vented and thereby solidified mold being vented, the tool is opened and the closed shape is removed after the tool has been opened, characterized in that the firing process and / or the venting process is regulated by means of detected and possibly prepared process parameters in accordance with any prescribable regulation.

2. The method as claimed in claim 1, characterized in that the control is based on individual process parameters, predefinable combinations of the process parameters or algorithms on the basis of the process parameters.

3. The method according to claim 1 or 2, characterized in that for the respective process section or process - shooting and / or venting - a maximum process duration is specified as a process parameter.

4. The method according to any one of claims 1 to 3, characterized in that during the shooting the pressure building up or prevailing in the overall system - sand bunker, tools, lines, etc. - is detected as a process parameter.

5. The method according to any one of claims 1 to, characterized in that during the firing the volume flow or the air flow in the overall system is detected as a process parameter - at any point.

6. The method according to, characterized in that the amount of sand blown into the tool is detected as a process parameter during firing.

7. The method according to any one of claims 1 to 6, characterized in that the course of the venting process and possibly the time of opening the tool is controlled via detected and optionally processed process parameters.

8. The method according to any one of claims 1 to 7, characterized in that the pressure profile within the tool is detected as a process parameter during the venting of the tool.

9. The method according to any one of claims 1 to 8, characterized in that during the ventilation of the tool, the air flow, in particular the amount of air flowing out of the tool, is detected as a process parameter.

10. The method according to any one of claims 1 to 9, characterized in that when venting the tool, a preferably electromagnetic vent valve is controlled such that the pressure prevailing in the tool drops, preferably linearly, while avoiding pressure jumps.

11. The method according to any one of claims 1 to 10, characterized in that the individual processes and / or the detected and / or determined process parameters are or can be compared with an optimal curve of the process, preferably via a graphic that can be shown on a display.

12. The method according to claim 11, characterized in that the individual process can be influenced interactively or automatically on the basis of the comparison or any deviations.

13. The method according to any one of claims 1 to 12, characterized in that the process duration is determined on the basis of the detected and / or determined process parameters.

14. The method according to any one of claims 1 to 13, characterized in that, based on the detected and / or determined process parameters, the respective process is monitored with regard to any errors or defects.

15. The method according to any one of claims 1 to 14, characterized in that the time for an automatic tool change is defined on the basis of the detected and / or determined process parameters.

16. The method according to any one of claims 1 to 15, characterized in that the maintenance interval is calculated on the basis of the detected and / or determined process parameters.