DE102015000547A1 - Mold removal tool for demolding body parts - Google Patents

Abstract

Dismantling tool (10) for demolding body parts (11) from a pressing tool, with at least one housing element (12) and with at least one push-off element (18), which is accommodated in a receiving region (14) of the housing element (12) and by means of which a Abdrückkraft (16) for demolding is exercisable, wherein the Abdrückelement (18) for demolding relative to the housing element (12) is designed to be movable. The push-off element (18) is formed from a plastic.

Description

The invention relates to a demolding tool for demolding of body parts from a pressing tool, with at least one housing element and at least one Abdrückelement which is received in a receiving region of the housing member and by means of which a Abdrückkraft for demolding is exercised, wherein the Abdrückelement for demolding relative to the housing element is designed to be movable.

Such a demoulding tool is used, for example, to remove deformed sheet metal components from a forming tool, that is, for example, from a mold half of a pressing tool. For example, body parts for a motor vehicle can be counted among these deformed sheet-metal components.

The use of demoulding tools can cause damage during the operation of press tools. These damages may relate to various components of the pressing tool, such as hold-down means by means of which the sheet metal components to be deformed are held on the pressing tool in the exactly aligned state for forming the sheet metal components. Substantial damage and the associated costs can also arise on so-called partial editions of the pressing tool. These partitions correspond to the contour negative molds of the pressing tool, based on which from undeformed sheet metal parts, the body parts are formed. It can even lead to the destruction of components that are used in the context of contouring of sheet metal components. In this case, for example contour cutting blades should be mentioned, by means of which the contour of the sheet metal components is cut out and which can easily break out.

Object of the present invention is to provide a demolding tool of the type mentioned, by means of which said damage can be at least reduced.

This object is achieved by a demolding tool according to claim 1. Advantageous developments of the invention are given by the dependent claims.

In order to provide a demolding tool of the type mentioned, in which damage to said components can be reduced, it is inventively provided that the Abdrückelement is formed of a plastic. The demolding tool corresponds for example to a so-called impression pin. The pressing member formed from a plastic, which corresponds for example to a plunger of the impression pin, on the one hand hard enough to demould body parts and additionally or alternatively to calm, so to dampen the movement of the body parts when pressed. On the other hand, the Abdrückelement is elastic enough to avoid breakage of the Abdrückelements. In the event of breakage of the push-off element (plunger), the danger is particularly great that a hold-down of the pressing tool is deformed, resulting in repair costs. Characterized in that the pressure element is made of plastic and not of a little flexible material, such as steel, the deformation (damage) of the blank or the hold-down can be effectively prevented and thus avoided.

Furthermore, damage to the partitions can be avoided. Due to production reasons, the operation of pressing tools leads to so-called empty strokes, in which the tool halves of the pressing tool are pressed against one another, without there being a sheet-metal component to be formed between the tool halves. This leads to contact of the Abdrückelements with the partial support. In contrast to known from the prior art plungers made of metal, which press in the Leerhüben in the partitions and damage them over time, can be done without damage by the use of the formed of a plastic Abdrückelements the idle strokes. The pressure element formed from a plastic is in fact particularly flexible and soft compared to a metal, so that it can give in contact with the partitions and elastically deformed. Damage to the partitions can thus be particularly far-reaching prevented when in contact with the pressing-off element formed of plastic.

It is clear that during demoulding, a plurality of said demolding tools and thus several ejection elements can be used. When using Abdrückelementen of a metal damage would occur at different points of the partitions, which can cause particularly high costs. However, this is avoided by the use of the pressing elements formed of plastic.

It is furthermore advantageous if the plastic is a polyamide, in particular a polyamide 6. Polyamides are particularly tough and strong plastics and therefore particularly well suited as a material for the Abdrückelement. Polyamide 6 is an injection-moldable plastic and can therefore be produced at particularly low production costs. So if the Abdrückelement is damaged, this is easy and inexpensive to replace.

It is furthermore advantageous if the pressure-exerting element is elastically deformable under the pressure-off force. Under the Abdrückkraft the Abdrückelement is movable relative to the housing member in which the Abdrückelement is guided. When demolding the Abdrückelement is partially pushed out of the housing element and in contact with the body part. When contacting and demolding of the body component, the push-off element is elastically deformed. The Abdrückkraft is applied, for example by gas pressure or by a coil spring, which is provided in the housing member, on the Abdrückelement. The deformation of the push-off element ensures that other parts brought into contact with the push-off element during demolding, such as the body component, remain undamaged. The Abdrückelement can also be used on sloping surfaces, which is a major advantage by design. On the inclined surfaces of the body part, the Abdrückelement can slide off without breaking. This is a considerable advantage compared to the metallic rams known from the prior art, since they can break off particularly easily on contact with inclined surfaces because of their high rigidity.

It is furthermore advantageous if the housing element is formed from a metal, in particular from steel. The housing element is characterized significantly more stable and stiffer than the Abdrückelement. If the push-off element is damaged, for example, if it kinks over a long period of use as a result of material fatigue, then the housing element formed from a metal remains undamaged, since this is not deformed by bent parts of the push-off element. This also represents a considerable advantage to known from the prior art, metallic plungers, especially in the event of breakage any, broken plunger parts can cause damage to the housing in their contact with the housing.

It is furthermore advantageous if an end region of the push-off element facing the body part comprises a crown. By the crowning the Abdrückelement can slide particularly well on sloping surfaces of the body part to be demoulded. Thus, in contrast to a flat surface on the end region, the push-off element tends rather to be elastically bent, that is to say deformed, and thus to reach an elastically deformed state by the crowning. In the elastically deformed state, a particularly good reassurance of the molded body parts can be achieved, since the elastic deformation (bending) a simple damping possibility is provided, based on which the movement of the body components comes to a standstill very quickly. The faster the body components come to rest, the faster their further processing can take place in subsequent processing steps.

It is also advantageous if the push-off element is rotationally symmetrical. Due to its rotationally symmetrical design, the push-off element has a particularly uniform load capacity with regard to at least one rotational symmetry axis. As a result, care must be taken when installing the Abdrückelements on no special orientation of the Abdrückelements over the housing element. This allows a low-cost replacement of the Abdrückelements in case of damage.

It is furthermore advantageous if the housing element comprises a tool engagement on an inner side of the housing end on a housing end facing the body part. By means of the tool engagement, the demolding tool can be screwed into the pressing tool and thus be releasably fixed there. The arranged on the inside of tool engagement, which is formed for example as a hexagon socket, is significantly less susceptible to damage than, for example, arranged on an outer side of the housing element hexagon.

It is furthermore advantageous if the push-off element is supported on the housing element by means of a spring element of the removal tool. The spring element is a particularly inexpensive way to support the Abdrückelement on the housing element and bias in the housing element.

It is furthermore advantageous if the spring element is held detachably in the housing element by means of a fastening element. The fastening element may for example be designed as a screw, by means of which the spring element is biased in the housing element. By this bias the Abdrückelement is supported particularly free of play in the housing element. By deeper screwing in the screw also the bias can be particularly easily enlarged.

It is furthermore advantageous if the pushing-off force can be exerted with elastic deformation of the spring element. The spring element is elastically deformed during deformation of the body parts in the pressing tool. When deforming the Abdrückelement is pushed into the housing element while the spring element is compressed by a certain spring travel. The spring element relaxes at least partially as soon as the tool halves of the pressing tool be moved apart and exerts the Abdrückkraft by means of the Abdrückelements. The Abdrückkraft can be particularly easily varied by the spring element is simply biased stronger, for example, by a designed as a screw fastener is screwed deeper into the housing element. Alternatively, simply a spring element with a greater spring stiffness can be used.

The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures can be used not only in the respectively specified combination but also in other combinations or in isolation, without the scope of To leave invention.

Further advantages, features and details of the invention will become apparent from the claims, the following description of preferred embodiments and from the drawings.

In the following, the invention is explained once again with reference to a concrete embodiment. This shows:

1 in a sectional view of an embodiment of a demolding tool according to the invention; and

2 a side view of an embodiment of a rotationally symmetrical Abdrückelements the Entformungswerkzeugs invention.

1 shows a sectional view of an embodiment of a demolding tool according to the invention 10 , The demoulding tool 10 , which is designed here as an impression pin, for example, for demolding of body parts, such as in 1 and in 2 schematically illustrated body part 11 be used from a pressing tool. Of the pressing tool is present only a highly abstracted illustrated tool half 42 shown. The demoulding tool 10 is present from a housing element 12 , from one in a recording room 14 of the housing element 12 received Abdrückelement 18 , made of a spring element 36 and from a presently designed as a grub screw fastener 38 composed. The housing element 12 In the present case, it is made of steel and thus designed to be particularly stable. The housing element 12 However, could also be formed of another suitable metal, as long as, for example, design-related requirements for the strength of the housing element 12 are met by the metal.

The demoulding tool 10 is how in 1 shown by means of a male thread at one end of the housing 13 of the housing element 12 trained thread 40 in the tool half 42 screwed. In this position, the body part 11 by means of the demoulding tool 10 from the tool half 42 be removed from the mold. To a particularly stable engagement for a tool, such as an Allen key, for screwing the demolding tool 10 to provide, includes the housing element 12 at the housing end 13 which is the body part 11 is facing on an inside 30 of the housing end 13 a tool intervention 34 , The tool intervention 34 is thus internal and in the present case designed as a hexagon socket, which is particularly robust compared to external tool interventions.

The present case designed as a helical spring spring element 36 is in a spring channel 31 of the housing element 12 arranged and present by the at one end of the housing 13 opposite end of the housing element 12 screwed fastener 38 biased. The spring element 36 So is by means of the fastener 38 releasably in the housing element 12 held and can therefore be easily removed.

The easy removal of the spring element 36 is advantageous in that the Abdrückelement 18 by means of the spring element 36 of the demoulding tool 10 on the housing element 12 is supported, with a breaker head 19 of the push-off element 18 by means of the spring element 36 to a contact surface 15 of the housing element 12 is pressed. Removing the push-off element 18 takes place in the present embodiment by unscrewing the fastener 38 , By removing the spring element 36 and then removing the push-off element 18 , wherein the fastener 38 , the spring element 36 and the push-off element 18 over the housing end 13 opposite end of the housing element 12 be removed.

In 1 is the push-off element 18 in one in the housing element 12 Built-in state shown without the push-off element 18 the body part 11 touched. As already mentioned, in this state, the ejection head 19 to the contact surface 15 by means of the spring element 36 pressed. When in contact with the body part 11 becomes the push-off element 18 shifted in the direction of the fastener, wherein the spring element 36 while exercising one of a spring travel of the spring element 36 dependent pushing-off force 16 is compressed. The Abdrückkraft is thus under elastic deformation of the spring element 36 on the push-off element 18 exercised. Accordingly, the Abdrückkraft 16 , which for reasons of clarity, only in 2 is shown, particularly easily varied by the spring element 36 simply by deeper screwing in the fastener 38 in the direction of the contact surface 15 is biased stronger.

The pushing force 16 is doing on the Abdrückelement 18 exercised once the body part 11 by a not shown here, the tool half 40 opposite half of the tool on the Abdrückelement 18 pressed while the Abdrückelement 18 in the direction of the fastener 38 is shifted, wherein the spring element 36 this pressing of the tool half, not shown here the Abdrückkraft 16 opposes.

During the movement of the push-off element 18 Slip off 21 of the push-off element 18 in a guide channel 32 of the housing element 12 , whereby thus the Abdrückelement 18 in the guide channel 32 is moved led.

From the synopsis of 1 and 2 it can be seen that the push-off element 18 on the one hand in an undeformed state 26 is shown, in which a the body part 11 facing end region 20 of the push-off element 18 not with the body part 11 is in contact. Furthermore, in 2 an elastic deformation, which is an elastically deformed state 24 of the push-off element 18 corresponds, shown. In the elastically deformed state 24 is the end area 20 of the push-off element 18 with the body part 11 in contact and the push-off element 18 becomes thereby along the guide channel 32 in the direction of the only in 1 shown fastener 38 shifted, the shift is not shown here. It exercises in 1 illustrated spring element 36 the pushing force 16 on the push-off element 18 out. Under the push-off force 16 is the push-off element 18 So elastically deformable (elastically deformed state 24 ), which in the present case by the dashed representation of a part of the Abdrückschaftes 21 as well as a crown 22 at the end area 20 of the push-off element 18 is illustrated.

By the crowning 22 is the push-off element in the direction of the body part 11 arched and is in contact with this in point contact. Due to the punctiform contact, the Abdrückelement 18 under particularly low friction and thus particularly gentle on the body part 11 slide.

The push-off element 18 is also rotationally symmetric with respect to an axis of symmetry 28 , Which present the longitudinal axis of the Abdrückelements 18 equivalent. Due to the rotationally symmetrical configuration, a particularly reproducible load introduction into the push-off element can take place during removal from the mold 18 respectively. In addition, when installing the Abdrückelements 18 in the housing element 12 no special precautions to be taken, in which the relative orientation of the Abdrückelements 18 to the housing element 12 to pay attention. It is important in the present embodiment during assembly only that the ejection head 19 at the contact surface 15 and the Abdrückschaft 21 during installation of the push-off element 18 in the housing element 12 in the guide channel 32 is introduced.

The push-off element 18 is made of a plastic, namely formed in the present embodiment of "PA 6" (polyamide 6). This is the push-off element 18 particularly elastically deformable. Contact with the push-off element 18 takes place for the body part 11 thus damage-free.

Claims (10)

Demoulding tool ( 10 ) for demolding body parts ( 11 ) from a pressing tool, with at least one housing element ( 12 ) and with at least one push-off element ( 18 ), which in a receiving area ( 14 ) of the housing element ( 12 ) and by means of which a pushing-off force ( 16 ) is exercisable for demolding, wherein the Abdrückelement ( 18 ) for demolding relative to the housing element ( 12 ) Is designed to be movable, characterized in that the push-off ( 18 ) is formed of a plastic. Demoulding tool ( 10 ) According to claim 1, characterized in that the plastic is a polyamide, particularly a polyamide. 6 Demoulding tool ( 10 ) according to claim 1 or 2, characterized in that the push-off element ( 18 ) under the pressure force ( 16 ) is elastically deformable. Demoulding tool ( 10 ) according to one of the preceding claims, characterized in that the housing element ( 12 ) is formed of a metal, in particular of steel. Demoulding tool ( 10 ) According to one of the preceding claims, characterized in that the body part ( 11 ) facing end region ( 20 ) of the push-off element ( 18 ) a crowning ( 22 ). Demoulding tool ( 10 ) according to any one of the preceding claims, characterized characterized in that the push-off element ( 18 ) is rotationally symmetrical. Demoulding tool ( 10 ) according to one of the preceding claims, characterized in that the housing element ( 12 ) on a body part ( 11 ) facing housing end ( 13 ) on an inside ( 30 ) of the housing end ( 13 ) a tool intervention ( 34 ). Demoulding tool ( 10 ) according to one of the preceding claims, characterized in that the push-off element ( 18 ) by means of a spring element ( 38 ) of the demolding tool ( 10 ) on the housing element ( 12 ) is supported. Demoulding tool ( 12 ) according to claim 8, characterized in that the spring element ( 36 ) by means of a fastening element ( 38 ) releasably in the housing element ( 12 ) is held. Demoulding tool ( 12 ) according to claim 9, characterized in that the pushing-off force ( 16 ) under elastic deformation ( 24 ) of the spring element ( 36 ) is exercisable.

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