DE102011053867A1 - Injection mold for production of plastic moldings with two tool halves, has channels that are closed by capping or clamping plate - Google Patents

Abstract

The injection mold has two tool halves which enclose a cavity with integrated inductors (8) for the direct induction heating geometrically limited form regions and/or the entire wall of the cavity in the mold halves. An inductor is placed into channels (4) and is fixed by blank holder (6) consisting of a ceramic material. The channels are closed by capping or clamping plate (2). The blank holder is also made of metal oxide or silicon dioxide.

Description

The invention relates to an injection mold for the production of plastic moldings with two mold halves with the features specified in the preamble of claim 1.

From the EP 0 505 738 B1 ( DE 692 22 213 T2 ) discloses a multilayer mold for molding thermoplastic material into finished parts comprising a molding having a contour surface and a heat-insulating layer bonded to the contour surface. The insulating layer has a lower thermal conductivity than the molded part. In one embodiment, the insulating layer surrounds an induction coil, which is provided as a heating device. As required, the induction coil is applied to a high frequency power source to selectively heat a portion of the surface of the cavity to be filled by the induction coil.

From the DE 201 21 777 U1 a device for the production of workpieces made of thermoplastic material with a mold is known which has cooling channels, which are flowed through by a cooling medium, in particular water. In particular, molten plastic is injected discontinuously into a cavity of the closed mold. The wall of the cavity, which reproduces the shape of the molded plastic part, is cooled at the contacting wall, so that the plastic solidifies after spraying and retains the shape given by the forming tool. At least the surface layer of the mold, which is hit by the molten plastic, is made of inductively heatable material, in total or only in discrete areas. There is further provided an electrical inductor, by means of which the surface layer can be heated. The thin surface layer of the wall of the tool is heated inductively to a temperature immediately before the impact of the molten plastic, which is close to the melting temperature of the plastic or equal to the melting temperature. After spraying water is entered into the cooling channels and the wall and thus also made of plastic molding are cooled to the extent that this is fixed when you open the tool and ejecting the part in itself.

The DE 43 08 008 A1 deals with the dynamic mold temperature control in injection molding by means of an injection mold. The heating of a geometrically limited molding area takes place up to a small depth at the open mold by means of an inductor. During the closing phase, the tool cools due to heat conduction, convection and radiation. The heating takes place at such a high temperature that only after complete mold filling in the mold wall, the solidification temperature of the plastic melt is reached.

The basics of the applied induction heating within the tool are, for. B. in the "Publication IKFF" of the University of Stuttgart under the name "Production of long plastic hands by injection molding" by A. Tewald, A. Laage and O. Thissen played. A fully integrated inductive heating and pulse cooling of injection molds is contributing to the 19th Stuttgart Plastics Colloquium, 9 to 10 March 2005, Symposium 3, "Plastics Processing and Processing", author A. Weber and W. Schinköthe (IKFF) published. The article is published in the "IKFF 2005". The inductive heating takes place by means of laid inductors below the cavity surface. The inductors are inserted into the channels and embedded therein by means of a ceramic mass. The inductive heat generation is based on the transformer principle. A high frequency (about 10 kHz to 500 kHz) high current AC current, the inductor, is surrounded by an alternating electromagnetic field of the same frequency. Since the material that encloses the cavity is a conductive material, in turn, short-circuited electrical currents are induced in a thin surface layer. Due to the power loss of these currents at the ohmic resistance of the material produces the desired heat, which is introduced in addition to heating the tool with a heat medium. In order to keep the heating of the inductor itself manageable, this is usually performed as a waveguide and flows through with water. The advantage over other methods of heating metals is above all the very high rate of heating that can be achieved, the direct heat formation in the material of the article to be heated and the very high power that can be introduced by a given surface.

The heat dissipation occurs in injection molding tools most often by a liquid cooling in the form of a constant flow through the tool base plates with a medium, which is then cooled outside the tool again. In part, in addition, rarely substitute, method with even higher dissipated heat flow used, such. As electrothermal processes (Peltier elements), heat pipes or the expansion of liquid carbon dioxide. Since the heat input into the tool is not continuous, but oscillates cyclically between zero and a maximum value, cooling with almost constant heat dissipation is usually sufficient, but not optimal for problematic parts. Here, pulse cooling creates a remedy, in which the heat dissipation only during the times when that is required by the heat input. This prevents the cooling of the tool to too low a temperature in the low-phase heat input and the associated poorer quality parts, especially at high cooling performance. In complete variothermal operation - ie with heating and cooling in alternation - inevitably creates a pulse cooling.

With this in mind, it is the object of the invention to further develop an injection mold of the generic type and to design it so that a modular construction is made possible, different current conductors can be inserted as inductors and these are nevertheless kept secured in the channels, without them being insulated To embed composite mass. By suitable measures should always be ensured that even conductors with different diameters in a defined range secured in the channels are kept and are easy to install and replaceable. Another sub-task is to make the arrangement of the inductors so that the channels in which they lie, can also be used for the cooling with. The insulating parts needed for the fixation of the conductor should be inexpensive to manufacture and use and have a very long service life and no wear.

The object is achieved by the invention by designing the injection mold according to the teaching of claim 1. Advantageous developments of the injection mold according to the invention are specified in the dependent claims in detail.

The solution according to the invention is characterized in that the inductor is fixed in the channel by means of at least one hold-down made of a ceramic material and that the channels including the hold-down means of a closure plate or clamping plate can be closed. This embodiment has the advantage that the inductor in the open groove-shaped channels can be inserted easily and that then at certain points or along the channel a variety of hold-down can be used, for example, by a screw, in particular grub screw in a hole the attached closing plate or clamping plate are screwed, is depressed. The hold-down can also be formed from the screw itself, which is extended and, for example, consists of ceramic material and presses on the inductor.

The hold-down can also be used as a block in the channel or in a receptacle within the channel and then, for example via a in a side, split threaded bore, wherein the first half of the thread in the hold-down and the second part of the thread in the made of steel existing tool plate is secured by a screwed screw. If, for example, a grub screw made of ceramic material or metal is used here, it can be inserted while at the same time pressing the hold-down device against the inductor.

As hold-down but can also be made of a ceramic material holder defined form, z. B. in H-form, can be used, so that the inductor is at the same time laterally electrically insulated by spreading the legs relative to the side walls. In addition, if the bottom wall of the channel is provided with an insulating layer, for example, a thin ceramic film is inserted, a hermetic electrical insulation is given. The coating can of course also be provided on the side walls of the channel. Also, the hold-down can have as a block in the longitudinal direction of the channel openings.

But it is also possible to provide the inductor with an insulating layer of known type at least outside, so that it is mounted electrically isolated in the channel. In this embodiment, then the further means for electrical insulation can be omitted and it only needs the hold-down to consist of such a material. The channel is introduced into the mold plate, which consists of magnetizable material.

After inserting the inductor and fixing it with the holding devices provided according to the invention, the channel can at the same time also be used as a cooling channel if the hold-downs are placed so that the cooling medium can flow laterally past the inductor. It can be introduced into the hold-down but also flow openings through which the cooling medium can flow through unhindered. The channel is sealed for this purpose by the sealing plate or clamping plate. Through the hold-down a turbulence of the cooling medium is also given to the flow edges, which is the heat dissipation in the pulse cooling beneficial. Also, the storage chambers, which may be larger than the channel width, be designed to accelerate this cooling effect at certain points. The cooling of the tool is required after spraying with the hot plastic mass, so that before the opening of the tool and the ejection of the molded part of this keeps the dimensional stability.

In a further embodiment, it is provided that the channel has a plurality of receptacles for Holding down. In another embodiment, it is provided that the inductor in a known manner consists of a tubular waveguide and that this is additionally traversed by a coolant or for rapid heating of the tool for the next injection molding process with a heating medium. So it can be done both via the channel and in addition or alone on the waveguide heating and cooling phase.

In order to increase the efficiency in the cooling of the cavity surface and in the heating by induction, it is expedient in the channel a longitudinal recess, for. B. shell-shaped, provide, in which the inductor is inserted with adapted form. As a result, larger surfaces are directly on the material of the mold plate. An inductor embedded in this way is pressed against the bearing surface by the hold-down device, which presses against the upper side of the inductor.

The tool can of course also in addition to the channels in which the inductor is laid, also have additional cooling channels in at least one mold half in order to achieve a faster curing of the plastic molding and thus to increase the working cycles of the tool.

The invention will be explained in the following with reference to the embodiments illustrated in the drawings.

In the drawings show:

1 one half of an injection molding tool in a schematic representation with an inductor arrangement and with cooling channels,

2 A first embodiment of a hold-down for the inductor according to the invention,

3 another embodiment of a hold-down for an inductor,

4 Another example of a hold down for an inductor in an injection mold and

5 in H-shaped design a hold-down according to the invention in a receptacle in the channel for the storage of the inductor.

In the illustrated in isometric view of the mold half of an injection mold according to 1 is a clamping plate 2 represented above it is a mold plate 1 , In this mold plate 1 , which is graduated, is a cavity 3 incorporated, which forms part of the closed cavity formed with the second mold half, which can be filled with liquid plastic by injection. The sprue bush, the ejector and other parts provided in this tool half or in the other tool half are not shown in the simplified illustration. Likewise, the holes for the guide columns for opening and closing the tool are not shown or the guide bushings that are required to remove the molded-off part of the tool can. These components are all known in a tool. The clamping plate specified here 2 can of course also be a pressure plate or a closing plate.

From the sketchy drawing are the channels 4 visible in the mold plate 1 are introduced and into which an inductor 8th according to the desired heating zones is laid according wave-shaped. The mold plate 1 consists of inductively heatable material, such as a steel plate. The wall to the cavity is relatively thin, so that a rapid heating is achieved in the desired manner. Furthermore, there are cooling channels in the mold plate 5 in the form of holes which are acted upon by the spraying of a plastic molding with coolant, so that in the shortest possible time the plastic molding so far solidifies that it can be removed from the mold.

According to the invention, the inductor 8th in the channels 4 fixed by means of retainers made of ceramic material. The ceramics-like substances, such as metal oxides, Betonide and silica, can also be used for the production of the blank holder. Such hold-downs have the advantage that they are electrically non-conductive, inexpensive to produce, dimensionally stable even at different mold temperatures and acid and gas insensitive.

The embodiment in 2 shows a section of the tool half according to 1 , namely a mold plate 1 in which a channel 4 for the inclusion of an inductor 8th is introduced, which may consist of a waveguide made of copper or a stranded wire or an aluminum conductor. Within the channel 4 is a channel depression 7 introduced, which is adapted in the lower part of the cross-sectional shape of the round conductor here. Of course, other cross-sectional shapes of the inductor can be used. To the inductor 8th to fix in this position, according to the invention in the form of the plate 1 connected platen 2 , which may consist of a non-magnetizable material, a threaded hole 10 introduced, and that vertically above the inductor 8th , In this threaded hole is a hold-down 6 introduced, which has the form of a grub screw and made of ceramic material. This ceramic screw is in the threaded hole 10 screwed in and presses on the surface of the inductor 8th and keep it in the channel well 7 firmly. The invention also shows that the channel 4 is formed larger, so that it can also be used as a cooling channel or as a channel for acting on the tool with a heat medium. For cooling a cooling medium is entered into the channel after the injection of the plastic molding. To allow rapid heating, the surface of the cavity 3 heated purely inductively, but can also by additional introduction of a heat medium in the channel 4 to be heated.

3 shows another embodiment in which the use of the channel 4 As a cooling channel is almost impossible. Here is a block-like hold-down 6 in the channel 4 or used in an enlarged shot. This block-shaped hold-down 6 is also made of ceramic material or, as previously stated, of another insulating material having insulating properties, so that the magnetic field is used only to the surface of the cavity 3 to warm up. In the channel 4 there is a channel depression 7 into which the inductor 8th is inserted. The channel depression 7 but can also form the channel itself. At intervals are hold-down 6 provided and used in the transverse recording. The hold down 6 is on the clamping plate 2 attaches and fixes the inductor 8th ,

A variation too 3 is in 4 shown. Here is namely the block-like hold-down 6 by means of a grub screw 9 on the mold plate 1 fixed. For this purpose, in the channel 4 the block-shaped hold-down 6 used. This has on the right side in a cup-shaped recess a thread which, with the associated threaded portion in a recess in the mold plate 1 a threaded hole 10 forms. When screwing in the grub screw 9 becomes the hold-down 6 in the recess 11 fixed and presses simultaneously with its arcuate portion on the surface of the inductor 8th ,

In 5 is another embodiment of a hold-down 6 represented, which has an H-shape. The two lower legs overlap a trained as a waveguide inductor 8th who is in the channel 4 lies. The channel 4 is with recordings 11 provided in which against rotation of the H-shaped hold-down 6 is used. The hold down 6 is about the threaded hole 10 , in half both in the mold plate 1 as well as in the thigh of the holder 6 is inserted, fastened. The H-shaped hold-down 6 has the advantage that it isolates with its thighs over the inductor 8th attacks. The inductor 8th may have an insulating layer on the outside, so that it is electrically opposite the mold plate 1 at the bottom side of the canal 4 isolated. But it can also be in the channel 4 be insulated, which is heat resistant and offers a wall and bottom insulation.

It can be seen that a channel 4 , with H-shaped hold-downs 6 is equipped, can also be used as a cooling channel. By closing the top by means of a closing plate or a clamping plate 2 can the channel 4 to be flowed through with a Kühlfüssigkeit. At the edges of the H-shaped hold-down 6 this creates turbulence, which promote the cooling of the tool in this area. The surface of the cavity wall 3 So it cools faster. Instead of a grub screw made of ceramic material can in the threaded hole 10 for fixing the H-shaped holder 6 also a steel screw to be screwed.

LIST OF REFERENCE NUMBERS

1

mold plate

2

platen

3

Cavity / cavity wall

4

channel

5

cooling channel

6

Stripper plate

7

channel deepening

8th

inductor

9

grub screw

10

threaded hole

11

admission

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0505738 B1 [0002]
• DE 69222213 T2 [0002]
• DE 20121777 U1 [0003]
• DE 4308008 A1 [0004]

Cited non-patent literature

• "Publication IKFF" of the University of Stuttgart under the name "Production of long plastic hands by injection molding" by A. Tewald, A. Laage and O. Thissen [0005]
• 19th Stuttgart Plastics Colloquium, 9th to 10th March 2005, Symposium 3, "Plastics Processing and Processing", author A. Weber and W. Schinköthe (IKFF) [0005]

Claims (11)

Injection mold for the production of plastic moldings with two tool halves, which enclose at least one cavity, with at least one or more integrated inductors for direct induction heating geometrically limited molding areas and / or the entire wall of the cavity in at least one of the mold halves, wherein the surface layer of the cavity inductively heatable material and the underlying inductors in the channels by means of high-frequency currents before the impact of the molten plastic on the surface layer inductively heated to a defined temperature and the injection mold has cooling channels in at least one mold half, of a cooling medium and / or of a heating medium can be flowed through, characterized in that the inductor ( 8th ) in the channel ( 4 ) by means of at least one hold-down ( 6 ) is fixed from a ceramic material and that the channels ( 4 ) including the hold downs ( 6 ) by means of a closing or clamping plate ( 2 ) are closable. Injection mold according to claim 1, characterized in that the channel ( 4 ) a variety of recordings for hold-down ( 6 ) having. Injection mold according to claim 1 or 2, characterized in that each hold-down device ( 6 ) by means of screws in the receptacle ( 11 ) is held secured or consists of a screw which is screwed into a threaded through hole in the closing or clamping plate. Injection mold according to claim 1, characterized in that the hold-down ( 6 ) has passages through which a cooling medium can flow and into the channel ( 4 ) A cooling medium after the injection of a molded part can be entered. Injection mold according to claim 1, characterized in that the inductor ( 8th ) consists of a tubular waveguide and that in the waveguide, a cooling medium or a heating medium can be entered. Injection mold according to claim 1 or 5, characterized in that the inductor ( 8th ) in a groove-shaped longitudinal recess of the channel ( 4 ) is enclosed at least half-sided and the hold-down ( 6 ) on top of the inductor ( 8th ) presses. Injection mold according to claim 1, characterized in that the hold-down ( 6 ) H-shaped and with its crossbar on the inductor ( 8th ) presses and this overlaps with the two thighs. Injection molding tool according to claim 4, characterized in that in addition to the channels ( 4 ) for receiving the inductor ( 8th ) Cooling channels ( 5 ) in the mold plate ( 1 ) of at least one mold half are incorporated. Injection mold according to claim 1, characterized in that the inductor ( 8th ) is surrounded by an electrical insulating layer. Injection mold according to claim 1, characterized in that the receptacles ( 11 ) Guides for the hold downs ( 6 ) exhibit. Injection mold according to one of the preceding claims, characterized in that the hold-down ( 6 ) consists of ceramic material, metal oxide, Betonid or silica.

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