DE102016001698A1 - Method for mass-producing plate elements and device for equipping a plate element with a molded component - Google Patents

Abstract

In a method for series production of plate elements, in particular of glass panes, with at least at its edge in each case molded component, in particular sealing component, it is provided that before the injection of the component to the edge of the plate member in each individual plate element, the thickness of the plate member is measured and the obtained measured value is taken into account when injecting the component to this plate element. A device for the serial equipping of plate elements, in particular of glass panes, with at least one component molded onto its edge, with an injection mold having at least two partial tools to be applied to the plate element from both sides, in particular for carrying out the aforementioned method, is characterized in that at least a sub-tool is movably received in a motion guide relative to the other sub-tool and that this motion guide is connected to a measuring device for the thickness of the plate element to be equipped.

Description

The invention relates to a method for the serial production of plate elements, in particular of glass panes, with at least one component molded onto its edge, in particular a sealing component. The invention further relates to a device for equipping a plate element, in particular a glass pane, with at least one component molded onto its edge, with an injection mold having at least two partial tools to be applied to the plate element from both sides, in particular for carrying out the aforementioned method.

Plate elements are to be regularly equipped with components at their edges. If these plate elements are, for example, glass panes and, in particular, glass panes to be used in motor vehicle bodies, components to be attached to the edge of the plate element may be seals. These come to rest between the glass pane and the body flange; they can compensate for the tolerances of the glass pane and body components involved.

Injection of a component to a plate element is a known technique. In known methods for the serial production of plate elements, the individual plate elements are placed in a corresponding device in which the component is molded. In order to adjust this device, in the prior art, the device is adjusted to the plate element series to be processed by once measuring the thickness of the apparently thickest plate element and transferring it into a setting of the device. In the prior art, therefore, only one thickness of a panel element series is taken into account when injecting components onto these panel elements. While the adjustment of the device for molding of the component to the plate elements in this one measured plate element is correct, deviations in the result of the injection of the component are achieved at different plate elements from one and the same series. The glass sheets of a series have a thickness tolerance. This is usually between 0.1 to 0.2 mm. Thus, if even thicker plate elements than the one measured on, threatens the processing of this plate element damage to the plate member by the injection mold. Namely, the injection molding tool regularly has sub-tools which are brought from both sides to the plate member to form a chamber for introducing the spray material.

If, on the other hand, plate elements are thinner than the one measured, there is a risk of leakage of material for the molded component. The result is a Formaustrieb, the material runs for example between adjacent edges of the injection mold and the plate member. This formaustrieb is then manually rework, which is complicated and expensive.

The invention has for its object to provide a method of the type mentioned, with the manufacture of plate elements without reworking and in good quality of the molded component is made possible. Furthermore, a corresponding device for carrying out the method is to be provided.

On the method side, this object is achieved in that prior to the injection of the component to the edge of the plate member at each plate member, the thickness of the plate member is measured and the obtained measured value is taken into account during injection molding of the component to this plate element.

The method according to the invention proposes not only to measure the apparently thickest plate element from a series of plate elements and to take into account each of these plate elements when the component is injection-molded, but to carry out a measurement of each individual plate element. The measured value obtained is assigned to this measured plate element and taken into account during injection of the component to this plate element.

In this way, advantageously, an optimum setting can be obtained during injection molding of the component in each individual plate element. It is thereby prevented that with the device described below for equipping the plate element is a damage of the plate elements. On the other hand, it is likewise prevented that a material ejection of material for the component occurs.

The inventive method can thus plate elements in series and in large numbers are produced in good quality.

According to a development of the method according to the invention, it is provided that the measurement of the plate element is carried out prior to its insertion into a device for equipping the plate element with the component. The inventive method relates to a series production of plate elements. It should therefore not be designed so that each individual plate element is inserted into the device for equipping and then done manually optimal adaptation of the individual components of this device. This is in the series production of plate elements, such as discs for solid models of No time for motor vehicles. Here, the production is largely automated, and it is measured with the inventive method before inserting the plate element in the finishing tool whose concrete thickness and then considered in the injection molding of the component.

The device-side solution of the object, for which independent protection is claimed, is characterized in that at least one part tool is movably received in a motion guide relative to the other part tool and that this motion guide is connected to a measuring device for the thickness of the plate element to be finished.

With the proposed measuring device for the thickness of a concrete to be processed plate member from a series can be measured in terms of its thickness, as provided by the method. The measured value obtained is transmitted on the device side to the part tool recorded in the motion control. Depending on the measured value, this sub-tool is arranged more or less far away from the other sub-tool. Both sub-tools are then applied from both sides of the plate member and form a cavity or a space in which the material for the component to be injected is introduced. In the subsequent plate element then takes place again measuring its thickness and in case of deviation, a change in the arrangement of the recorded in the motion guide sub-tool. Thus, according to the method of the invention, each individual plate element is measured and each measurement result is assigned to each individual plate element in its equipment with the component.

According to a development of the device according to the invention it is provided that a part tool forms a support saddle for the plate element and that this support saddle is received in the motion guide. The plate element is placed on the support saddle, the other part tool is then arranged above the plate element. The support saddle is accommodated in the motion guide, so that it can be lowered to demould the device according to the invention downwards anyway. After removing a plate element already equipped with the component, a next plate element is placed on the support saddle. This is then approximated with that in the motion guide as far as the other part tool, as previously determined in the measurement of the thickness of this now resting plate element. After closing the injection molding tool, the component can be molded.

The support saddle is easily added vertically translationally movable in the motion guide. This movement can be generated by a spindle and by a diagonal arrangement.

For a further embodiment of the device according to the invention, it can also be provided that the measuring device has a non-contact measuring instrument or at least one push-button for the thickness of the plate element. It is necessary to quickly measure the thickness of the plate member so that its serial production is not hindered.

Embodiments of the device according to the invention are illustrated in the drawing. Show it:

1 FIG. 2 is a schematic sectional view of an apparatus for equipping a plate member with a molded component according to a first embodiment; and FIG

2 : A schematic view of a device for equipping a plate element with a molded component according to a second embodiment.

In 1 shown and with the molded component 2 to be equipped plate element 1 is formed in this embodiment as a glass pane. The plate element 1 is in an injection mold 6 inserted, this injection mold 6 is from a support saddle 3 and other sub-tools 4 . 5 educated.

With the two part tools 4 . 5 as well as the support saddle 3 a chamber is provided which immediately provides the space for a to be introduced into the chamber injection molding compound. By curing this spray mass 2 again a design for the component 2 formed. The molded component 2 includes the edge of the plate element 1 completely and still has one from the edge of the plate element 1 protruding tongue.

When molding this component 2 to the plate element 1 has been prevented with bearing saddle 3 and upper part tool 5 Damage to the plate element takes place. Furthermore, it has also been prevented that Formaustrieb in column between plate element 1 and involved molds 3 . 5 exit.

The reason for this is a prior measurement of the thickness x of the plate element 1 and a consideration of this measure x at a height adjustment of the support saddle 3 along double arrow y. The adjustment of the support saddle 3 takes place for each individual plate element 1 in accordance with the previous measurement of the thickness x of this plate element 1 ,

In the second embodiment, the support saddle 3 slimmer trained. He lies on a diagonal saddle arrangement 8th on. On this diagonal saddle arrangement 8th a spindle acts 7 in the fixed part tool 4 is included. The rotary arrow 9 shows a rotation of the spindle 7 along double arrow z in a displacement of the helical-saddle arrangement 8th is implemented. From the displacement of the diagonal arrangement 8th then follows again raising or lowering of the support saddle 3 along double arrow y.

Claims (7)

Method for the series production of plate elements, in particular of glass panes, with at least part of its edge injection-molded component, in particular sealing component, characterized in that before the injection molding of the component ( 2 ) to the edge of the plate element ( 1 ) at each individual plate element ( 1 ) the thickness (x) of the plate element ( 1 ) and the measured value obtained during injection molding of the component ( 2 ) to this plate element ( 1 ) is taken into account. Method according to claim 1, characterized in that the measuring of the plate element ( 1 ) before its insertion into a device for equipping the plate element ( 1 ) with the component ( 2 ) is carried out. Apparatus for the serial equipping of plate elements, in particular of glass panes, with at least one component molded onto its edge, with an injection mold having at least two partial tools to be applied to the plate element from both sides, in particular for carrying out the method according to claim 1 or 2, characterized in that at least one sub-tool ( 3 . 4 . 5 ) in a motion guide relative to the other part tool ( 3 . 4 . 5 ) is movably received and that this movement guide with a measuring device for the thickness (x) of the plate element to be equipped ( 1 ) connected is. Apparatus according to claim 3, characterized in that a part tool a support saddle ( 3 ) for the plate element ( 1 ) and that these support saddles ( 3 ) is recorded in the motion guide. Apparatus according to claim 4, characterized in that the support saddle ( 3 ) is received vertically translationally movable in the motion guide. Apparatus according to claim 5, characterized in that the support saddle ( 3 ) has at least one spindle or a Schrägsattelanordnung as a movement guide. Device according to one of the preceding claims, characterized in that the measuring device for the thickness (x) of the plate element ( 1 ) has a non-contact measuring instrument or at least one button.

Images