Patent Description:
The apparatus, the method and the capacitor plate set are provided for producing the particle foam part by using electromagnetic waves, whereby foam particles are welded into the particle foam part by means of the electromagnetic waves. The energy required for welding is applied to the foam particles by means of the electromagnetic waves. The apparatus, the method and the capacitor plate set can in particular be used in the manufacture of a shoe sole or part of a shoe sole, particularly a midsole or part thereof. The invention also relates to a shoe sole or part of a shoe sole, in particular a midsole or part of a midsole, manufactured in this manner.

In <CIT> process for sintering moist thermoplastic foam particles is described. The particles are dielectrically heated and simultaneously compressed. Electromagnetic waves with a frequency of about <NUM> to <NUM> are applied.

Document <CIT> describes a similar procedure. In this process, foam particles are moistened with an aqueous solution and exposed to an electromagnetic field with a frequency of about <NUM> to <NUM>.

Document <CIT> describes a process for welding expandable polystyrene foam particles. In this process particles are moistened with an aqueous solution and exposed to an electromagnetic field of <NUM> to <NUM>.

<CIT> discloses a process in which polymer particles of polyolefins, which are wetted with a liquid medium, are heated with electromagnetic waves, in particular microwaves. The temperature in the mold is controlled by controlling the pressure in the mold.

<CIT> relates to a method for producing a molded part, in particular a component of a sporting good. The method includes providing a mixture of a polymer melt and a foaming agent and injecting the mixture into a mold.

<CIT> describes a process for producing particle foam parts in which a mixture of foam particles and dielectric transfer liquid is heated by means of electromagnetic waves to fuse the foam particles into a particle foam part. Radio waves or microwaves are used as electromagnetic waves. The material of the foam particles is formed from polypropylene (PP).

In spite of these considerable efforts, which have been ongoing for a long time, no machines with which foam particles are welded by means of electromagnetic waves have so far become established in industrial production. One of the main reasons for this is that the heat cannot be uniformly introduced into the foam particles, and does not result in an even welding within the particle foam part.

In commercial use, therefore, machines that weld the foam particles by using steam have been used primarily up to now. However, these machines have the disadvantage that the energy input is inefficient. Furthermore, the particle foam parts are still moist after welding and can therefore not be further processed immediately. As the heating is done from the outside towards the inside, the interior part of the component cannot always be welded with sufficient quality. In addition, the devices for generating steam are much more expensive than a generator for electromagnetic waves.

Welding foam particles with electromagnetic radiation requires a high energy provision to the foam particles, which are located in a molding tool for this purpose. In addition, the energy input into the foam particles should be as uniform as possible in order to achieve uniform heating and thus uniform welding of the foam particles.

One problem is that the electrodes and the corresponding molding tool are usually of different sizes. The molding tool has to be exchanged depending on the product to be produced. Therefore, different molding tools are used in a fixture, which may differ in size. The molding tool is usually a bit smaller than the electrode, in order to accommodate the molding tool completely within the electric field of the plate capacitor. The electrode therefore usually protrudes a little to the side of the molding tool. This creates an electric field that is not used. The capacitance of the capacitor is greater than necessary. As a result, the capacitor takes up more charge and thus also more energy than necessary.

Another problem particularly with regard to the production of shoe soles or parts of shoe soles, in particular midsoles or parts thereof, is the complex three-dimensional geometry of such parts. For example, shoe soles almost never have a constant thickness along their longitudinal and/or medial-to-lateral extension. This complicates the welding process in that it is hard to achieve a constant and homogeneous welding of the particles throughout all regions of the sole.

The applicant of the present patent application has improved known devices and methods for welding foam particles by means of electromagnetic waves and the corresponding processes, particularly in the context of the manufacture of shoe soles. These devices and processes are based on the technology described in the published documents <CIT> and <CIT> and the <CIT>, as well as the published applications <CIT> and <CIT> owned by the applicant of the present application, to which reference is made in connection with the invention as described below, in particular with respect to the devices, processes, and materials, but not exclusively.

The present invention is, in particular, based on the problem of increasing the efficiency of the energy input and of using the electric field more effectively in the production of particle foam parts, particularly shoe soles / midsoles, by welding foam particles by means of electromagnetic waves.

The invention is further based on the problem of increasing the quality of shoe soles or midsoles produced by fusing foam particles by use of electromagnetic fields, even if they have a complex three-dimensional geometry and, in particular, a varying thickness.

These problems are addressed and at least partially solved by the different aspects of the invention as discussed in more detail below.

A first aspect of the invention is provided by an apparatus for the production of a particle foam part, particularly a shoe sole or part of a shoe sole (e.g., a midsole or part thereof).

In an embodiment, the apparatus comprises a molding tool which defines a molding cavity, wherein at least two capacitor plates are arranged adjacent to the molding cavity, which are connected to a radiation source for electromagnetic radiation, wherein the electromagnetic radiation source is adapted to emit electromagnetic radiation, and the molding tool is formed from at least two molding halves, wherein at least one of the two capacitor plates is formed from several segments, so that the surface of the capacitor plate array with the several segments can be adapted based on the shape of the product to be fused within the molding cavity.

For example, the capacitor plate formed from segments is designed as a segmented electrode. It can be composed of several segments. This is relatively easy to achieve, especially with a flat electrode or capacitor plate. However, it is not only possible with flat electrodes, but also with contoured electrodes, such as electrodes for the production of shoe soles / midsoles.

For example, the segments are shaped in such a way that by removing and/or adding the individual segments to form the capacitor plate, its surface can be adapted in its shape and size, and especially in its lateral dimensions, to the shape of the part to be produced in the molding tool.

Preferably, the segments of the capacitor plate are detachably connected electrically and mechanically. In this way, individual segments can be removed or added in order to adapt the surface of the capacitor plate to the size of the molding tool.

An electrically conductive connecting element is can provided, which electrically connects two or more segments at their edges. For example, electrically conductive metal elements such as copper or brass foils can be used, against which the edges of the segments of the electrodes are clamped so that there is an electrical connection to all segments of the electrodes.

Also, the segments can have areas at their edges that interlock when the segments are joined together. This means that the electrical and mechanical connection can be made particularly reliably and relatively cheaply at the segment joints. The edges or areas can be designed for this purpose, for example, as a stepped seam.

On the other hand, the segments can also be provided in a non-interlocking manner, in particular without such interlocking areas, which may be beneficial to allow in-mold-assembly, i.e. assembly of the segments (or addition or removal of a segment or segments) without having to dismantle the molding tool/capacitor plates.

Preferably, the segments are detachably attached to an insulator. The insulator serves to hold the segments in place. The insulator is preferably suitable for high voltage and does not cause significant losses in RF radiation, otherwise it would heat up. Also, the used material should not display meaningful reaction to the electromagnetic field that is used in terms of its field permittivity and dielectric loss, since this would again lead to unwanted heat up. Therefore, a dielectric material with a preferably low dielectric loss factor as well as a low dielectric permittivity is preferred. For example, a ceramic material and/or a plastic material may be used. Example dielectrics polymers that may be used include: PEEK, PTFE, PE, PS, PET. Example ceramic materials that may be used include: aluminum oxide, aluminum nitride, aluminum silicates.

The segments of the electrode or capacitor plate can be attached to the insulator, for example with screws. However, other means of fastening, such as plug connections, bolts, clamping elements, etc., can also be used to fasten the segments to the insulator.

For example, at least one segment of the capacitor plate formed by the segments is electrically connected to the radiation source.

According to one option, the segments of the capacitor plate can be permanently attached to an insulator and can be switched on or off individually to adjust the size of the capacitor plate. This can be done relatively easily, especially if the segmented capacitor plate is flat, or if two flat segmented capacitor plates form the capacitor for the exposure of the particles to radiation.

In this case, the segments are preferably electrically isolated from each other and each segment is separately connected to the radiation source, for example via a high-frequency line in case a high-frequency generator is used as radiation source.

Advantageously, the segments are each connected to a tunable resonant circuit and can be switched on or off, or activated or deactivated, individually or in groups, by tuning the respective resonant circuit.

In particular, the segments may each form a partial capacitor, which is connected to the tunable resonant circuit.

Each supply line can be assigned a regulating capacitor with which the energy supplied via the respective line can be adjusted independently of each other. By controlling the energy supply on the individual lines, it is thus possible to control which segment(s) of the capacitor is operated. By switching individual segments on and off by means of resonant circuit tuning, the size of the capacitor plate can be adapted to the size of the molding tool with regard to its radiation-emitting surface. This means that it is not necessary to mechanically remove or attach individual segments depending on the molding tool in order to adapt the surface of the capacitor plate.

Preferably, the segments together form a contoured capacitor plate.

In particular, the segments can be arranged on both sides of the molding cavity and, in particular, form a segmented capacitor plate there.

The segments can also be arranged on only one side of the molding cavity and form a segmented capacitor plate there. On the other side of the molding cavity, for example, a continuous capacitor plate can be arranged.

Also, on the other side of the molding cavity an electrically conductive area of the molding tool or an electrically conductive molding half can serve as a capacitor plate opposite the segmented capacitor plate. However, in the case of a contoured surface, an electrically non-conductive molding half is preferred, as it is easier to create a homogeneous electrical field. Moreover, using an electrically conduction molding half would entail the risk of burning the manufactured component in the regions adjacent to this molding half, so also from this perspective a non-conducting material is preferred.

If both molding halves were electrically conductive, one molding half would have to be connected to an RF line of radiation, which would be relatively difficult or very costly to accomplish.

It is advantageous if at least one of the capacitor plates formed from the segments is electrically connected to the radiation source, while for example the other capacitor plate or its segments are electrically grounded or connected to earth.

In particular, the segments can each have a geometry which, when the segments are combined, produces a capacitor plate whose geometry (particularly, its lateral extension) is adapted to the geometry and size of the molding tool. For example, the segments can be rectangular, preferably in different dimensions, in order to form differently sized rectangles as capacitor plates by combining several segments depending on the size of the molding tool to be irradiated.

The edges of adjacent segments are advantageously parallel to each other to form the capacitor plate by combining several segments.

In particular, it is advantageous to arrange the individual segments in such a way that a central square segment is provided and additional segments extend along the sides of the square segment. In this way, rectangles of different sizes can be created by combining several segments. A further ring of additional segments can be provided.

The segments can, for example, be designed as sheet metal parts. The segments may be flexible. It is advantageous if they are made of a metal with good electrical conductivity or a metal alloy with good electrical conductivity.

According to a second aspect of the invention, a capacitor plate set is provided for an apparatus for manufacturing a particle foam part, in particular a shoe sole or part of a shoe sole (e.g., a midsole or part thereof).

In an embodiment, the capacitor plate set comprises at least one first capacitor plate segment adapted to be attached to an insulator and comprising a terminal area adapted to be connected to a radiation source for generating electromagnetic radiation, one or more second capacitor plate segments, wherein the first capacitor plate segment and the second capacitor plate segments are adapted to jointly form a capacitor plate whose area is adaptable in size to the size of a molding tool for producing the particle foam part.

The capacitor plate segments form a set of several objects belonging together to form at least one or also several segmented capacitor plates which are adaptable in their size to the size of the molding tool used to weld to the foam particles for manufacturing the particle foam part.

Preferably, the capacitor plate segments are detachably electrically and mechanically connectable.

In particular, the second capacitor plate segments may also each include a terminal area for connection to a radiation source for generating electromagnetic radiation.

Each capacitor plate segment may be designed in such a way that it is electrically isolated from the other capacitor plate segments in the capacitor plate formed from it and can be connected or disconnected from the energy source, e.g., by a tunable resonant circuit.

Preferably, the capacitor plate set is designed for use in an apparatus according to one of the aspects of the invention.

A third aspect of the invention relates to a process for the production of a particle foam part, in particular a shoe sole or part of a shoe sole (e.g. a midsole or part thereof).

In an embodiment, the method comprises the following steps: a. ) filling foam particles into a molding cavity of a molding tool, wherein at least two capacitor plates are arranged adjacent to the molding cavity, which are electrically connected to a radiation source for electromagnetic radiation in order to generate electromagnetic radiation; b. ) welding of the foam particles by the electromagnetic radiation between the capacitor plates; and c. ) demolding; wherein d. ) at least one of the two capacitor plates is formed from a plurality of segments, and the area of the at least one capacitor plate is adapted to the size of the molding tool by combining the radiation-generating segments.

The foam particles are heated in the molding tool so that they are welded to form to the particle foam part. Heat is applied to the foam particles using electromagnetic RF radiation.

It is advantageous to detachably connect the segments electrically and mechanically in order to combine them.

According to one option, the segments can be arranged electrically isolated from each other and, e.g., by tuning an resonant circuit connected to a respective segment, can be switched on or off to combine them. This allows the area of the capacitor plate emitting the radiation to be adjusted without having to mechanically remove or mechanically add segments. In particular, this eliminates the need to mechanically separate or connect segments to the radiation source when adjusting the area of the capacitor plate, which would require a great deal of effort.

In particular, the segments can each form a partial capacitor.

It is advantageous to use an apparatus according to the invention and/or a capacitor plate set according to the invention to carry out the described process.

The foam particles are preferably made of, or comprise, expanded thermoplastic materials, especially thermoplastic polyurethane (TPU), polylactate (PLA), polyamide (PA), polyether block amide (PEBA), polyethylene terephthalate (PET), polybutylene terephthalate (PBT), or thermoplastic polyester ether elastomer (TPEE). The foam particles may also be a bead containing multiple polymer types in one foam particle or the foam particles may be a mixture of different particles of different foam polymers or combinations thereof. Preferably, the foam particles consist of <NUM> % by weight of one or a mixture of these materials. These foam particles are particles that comprise a so-called bead foam, also known in the art as a pellet / particle foam. Often the foams derived from the use of connected foam particles are given the designation "e" to denote the bead form of the polymer foam component, for example, eTPU.

The foam particles from these materials are preferably heated mainly by direct absorption of RF radiation. This means that the heat is not or only to a small extent heated by a heat-transferring medium, such as water, which absorbs the RF radiation and transfers it to the foam particles. On the one hand, the direct absorption of RF radiation is very efficient and also allows the welding of foam particles made of materials such as polyethylene terephthalate (PET), whose softening temperature is above <NUM> (usually around <NUM>), which is not possible by heating with an aqueous heat transfer medium. In addition, the use of such heat transfer agents can be avoided or reduced, thus improving the quality of the end product.

The addition of a heat transfer medium is also possible within the scope of the present invention, however.

The electromagnetic RF radiation preferably has a frequency of at least <NUM> or at least <NUM>, in particular at least <NUM> or at least <NUM>, preferably at least <NUM>. The maximum frequency may be <NUM>. Specific (center) frequencies that may be used, and for which radiation sources are easily commercially available, are, for example, <NUM>, <NUM>, <NUM>, <NUM>. However, even (center) frequencies of <NUM> or <NUM> may potentially be used.

To generate the electromagnetic RF radiation, the capacitor plates are preferably arranged on the molding tool which is otherwise made of an electrically insulating material. A high-frequency voltage with an amplitude of about at least <NUM> kV up to some kV, preferably at least <NUM> kV and in particular at least <NUM> kV is applied to the capacitor plates.

With such electrical voltages, a power in the range of <NUM> kW to <NUM> kW can be transferred to the foam particles in the molding cavity. This allows even large-volume particle foam parts, and/or shoe soles or parts thereof, to be reliably produced with very short cycle times of about <NUM> seconds to <NUM> minutes.

The foam particles can be compressed in the molding tool. The molding tool can be designed as a crack gap molding tool, for example. In it, the foam particles are mechanically compressed in addition to the compression effect created by their thermal expansion during the welding process.

The molding tool is preferably made of a material that is essentially transparent (e.g., in the sense of a low relative permittivity) to the electromagnetic RF radiation that is used. Possible materials include polytetrafluoroethylene (PTFE), polyethylene (PE), especially ultra-high molecular weight polyethylene (UHMWPE), polyether ketone (PEEK). Also semi-transparent material may be used, however, like polyethylene terephthalate (PET), polyoxymethylene (POM), or polyketone (PK).

In the case that the segments can be connected or disconnected individually or in groups to form the capacitor, the electromagnetic radiation source can be designed as part of a generator resonant circuit. Lines for guiding the electromagnetic waves form a tool resonant circuit together with a pair of segments each forming a partial capacitor. By changing an inductance or a capacitance, the tool resonant circuit can be tuned and forms a tunable resonant circuit, through which the transmission of power can be blocked or enabled in a targeted manner.

A control device for controlling the tunable resonant circuit can be designed in such a way that the power supply from the generator resonant circuit to the tool resonant circuit, which can be designed as a tunable resonant circuit, can be switched on or enabled or interrupted by its tuning. In this way, the relevant segment is added to or removed from the capacitor plate formed from several segments which applies electromagnetic radiation to the molding tool during the welding process.

The power that can be transmitted into the molding cavity by means of tuning the resonant circuit can be in the range of <NUM> kW to <NUM> kW, depending on the dimensioning of the generator and the lines with which the generator resonant circuit(s) is connected to the tunable resonant circuit(s).

One of the two capacitor plates can be electrically connected to ground in all options of the different aspects of the invention discussed herein. The other capacitor plate can be directly connected to the radiation source either directly or through one or more of its segments, whereby the radiation is fed to this capacitor plate as electromagnetic waves relative to ground.

A fourth aspect of the present invention, which may be combined with the above-discussed first, second and/or third aspect of the invention and all their possible options, modifications and embodiments (if not ruled out physically or technically, of course), is provided by an apparatus for the production of a particle foam part, particularly a shoe sole or part of a shoe sole (e.g., a midsole or part of a midsole).

In an embodiment, the apparatus comprises: a. ) a molding tool which is formed from at least two molding halves and which defines a molding cavity; b. ) at least two capacitor plates which are arranged adjacent to the molding cavity; wherein c. ) at least one of the capacitor plates is connected to a radiation source; and wherein d. ) at least one of the capacitor plates comprises several segments that have an adaptable distance to the molding cavity.

We point out that the capacitor plates being arranged "adjacent" to the molding cavity does not mean that the capacitor plates are in direct contact with, or form the walls of the molding cavity. Rather, what is implied by the feature is that the capacitor plates are arranged "around" the molding cavity and at a distance therefrom that allows flooding or irradiating the molding cavity with an alternating electromagnetic field that is suitable to create the desired welding of the foam particles within the molding cavity. Typically, components or parts of, e.g., the molding tool (in particular, parts which are transparent or largely transparent to the used electromagnetic radiation) will be arranged between the capacitor plates and the molding cavity (see, for example, the detail discussion of possible embodiments with regard to the figures in the sections below), and the shape and dimensions of the molding cavity are defined by the molding tool, rather than the capacitor plates themselves (which makes it generally possible to use different molding tools with different molding cavities between the same set of capacitor plates).

In the disclosed apparatus, the multiple segments (also called "electrode elements" in the following) are designed in a manner that allows for manual or automatic shape changes of the respective capacitor plate (also referred to as an "electrode" in the following). These shape changes are used to locally control the electric field strength within the molding cavity, and therefore control the material heating in that location, as will be further explained in more detail below. This modularity brings both manufacturing and product benefits.

Former efforts in mold development were focused on sophisticated electrode design, guided by exact simulation, with the goal of trying to match the electromagnetic field inside the molding cavity as closely as possible to the desired values by the design of the electrodes/capacitor plates directly. Since particle fusion by means of electromagnetic radiation (in particular RF radiation) is based on dielectric heating of the target materials, the homogeneity of the heating is dependent on an even electric field distribution at the working frequency. The field is typically created between (at least) two conductive electrodes/capacitor plates, an active one and a grounded one, between which an insulating molding tool and the target part (here: a shoe sole or part thereof) are sitting. Commonly, the conductive metal electrodes/capacitor plates are partially shaped to adjust the field distribution to the disturbances caused by the molding tool and the part that is being molded. If this shaping is not correct, multiple parts of the tooling must be change to optimize the electrode design. Also, the electrode shape cannot be changed during the process, or between process loops to adapt to changed product requirements or material variations.

The disclosed apparatus, by contrast, allows for flexible changes of the tooling setup, in particular regarding the distance between the active and passive electrodes/capacitor plates, and particularly on a grid resolution. The change can be manual or active, depending on the chosen actuation. The change be fixed for the part that is currently being manufacture, or be changed even during the process to allow even more control than is currently available. For example, depending on the selected grid resolution, one can locally increase or decrease the field strength and hence set the heating rate and maximum temperature that the target experiences. This enables, for example, a fast adaption to new mold geometries and locally tuned part properties.

At least one of the electrodes/capacitor plates is therefore split into a collection of elements or segments (e.g., a grid of such elements/segments), which can be moved parallel to the z axis, which is taken to lie along the direction from the electrode/capacitor plate towards the molding cavity, but which are preferably at all time still electrically connected to a main body of the electrode (be it the active or passive side, preferably the passive), which is then further connected to a radiation generator or ground potential (preferably ground potential as this allows for a simpler construction). The distance between the electrode elements/segments and the molding cavity, and hence between the opposing electrodes/capacitor plates, influences the local field strength in the gap between the two electrodes/capacitor plates, and hence within the molding cavity. This distance can be set by any form of actuator and the distance control can take place on the individual segment level. It is particularly possible to keep all elements always in electrical contact and to not have the segment control system interfere with the electromagnetic fusion process.

For example, a set of runs was performed using an aluminum breadboard that holds an array of screws. The screws were manually set to different heights. For fusion of particles of expended thermoplastic polyurethane (eTPU), clear differences in the heating rate and maximum temperature were achieved for the different electrode configurations. The properties of the manufactured parts also changed locally and accordingly.

In summary, by using the disclosed apparatus, improved prototype/part quality can be achieved, and it is highly suitable for product testing and/or prototyping. Quicker process development for new products can thus result and lower cost tooling is available. Varying the distance of the segments to the molding cavity, and with that the distance between the two electrodes/capacitor plates, during the fusion process can also allow for new methods of process optimization and thus product optimization.

Further details, options and embodiments of such an apparatus as well as some of the related technical advantages are discussed in the following.

As already mentioned, the segments can be electrically connected to an electrically conductive electrode main body. The electrode main body can in particular be on ground potential.

Particularly, the capacitor plate that is connected to the radiation source (e.g., a generator for RF radiation) can be a first capacitor plate on one side of the molding cavity, and the capacitor plate that comprises the several segments that have an adaptable distance to the molding cavity can be a second capacitor plate on an opposite side of the molding cavity.

For example, as mentioned in the beginning, an "active" capacitor plate connected to the radiation source and a "passive" capacitor plate containing the adjustable segments can be arranged on opposing sides of the molding cavity and enclose the molding cavity in between them, and by adjusting the distance of the segments to the molding cavity effectively the distance between the two capacitor plates is also locally changed. In the molding cavity, this leads to a change in the field strength distribution of the electromagnetic field flooding the molding cavity, and hence at the particle surfaces that are being welded under the influence of the electromagnetic field.

The distance of the segments to the molding cavity can be individually adjusted by mechanical and/or electrical actuator means.

The segments can in particular be arranged in a two-dimensional grid, in particular in a rectangular grid.

The grid density (i.e., the number of adjustable segments per unit area) can also vary locally. For example, corresponding to the toe region and/or heel region of a shoe sole that is to be manufactured, segments can be arranged with an increased density compared to other parts of the sole, to allow for an even higher degree of control of the welding process in these regions.

Alternatively, or in addition, to changing the density of the arrangement of the segments, also their radiation-emitting surface area can be locally changed. For example, screws or pins with different head sizes can be used (typically: smaller head sizes in regions with a higher density of segments).

As just mentioned, the segments can be provided as screws or pins adjustably connected to the electrode main body. The screws can for example be metal screws that are screwed into the electrode main body, and the electrode main body can also be made from metal or comprise metal, for example aluminum.

A cover sheet, or cover layer, of electrically non-conductive material can further be arranged on the electrode main body and comprise openings in which the screws or pins are arranged.

Such a cover sheet can be used to increase the stability of the arrangement of the segments itself, e.g. by providing lateral stabilization to the segments, particularly when they are moved out a long distance from the electrode main body (e.g., if the screws are screwed out from the base plate almost to their full length). But it can also serve to provide a stable platform on which further parts of the molding tool that lie between the electrode/capacitor plate and the molding cavity may rest. Without this sheet or layer the adjustable position of the segments would lead to a varying support surface for the adjacent components of the molding tool, which not only necessitates a more complicated construction but can also be detrimental to the stability of the tool.

Such a cover sheet can be made from or comprise an electrically insulating cover. Preferably, the cover sheet is made from or comprises one or more of the following materials: polytetrafluoroethylene (PTFE), polyethylene (PE), especially ultra-high molecular weight polyethylene (UHMWPE), polyether ketone (PEEK), a thermoplast, a duroplast, polyethylene terephthalate (PET), polyoxymethylene (POM), polystyrene (PS), an insulating mineral material.

One option is that each of the adjustable segments can be set to one of at least the following four positions: removed or electrically disconnected, a low position, a medium position, a high position.

The adjustable segments can, for example, be electrically disconnected by tuning of a resonant circuit as disclosed herein with regard to the other aspects of the invention, and/or by simple switch-type elements.

Rather than being adjustable to predetermined positions, some or all of the segments can also be adjusted continuously in their positions (i.e. at any position between a lowermost and an uppermost position).

Having a finite set of predetermined position can facilitate the operation of the apparatus, while have the possibility of a continuous adaption of the segment position (in the z direction, i.e. towards and away from the molding cavity) increases the amount of influence and control that can be exerted on the electromagnetic field strength distribution.

It may be possible that the position of the segments can be adjusted while the molding cavity is irradiated or flooded with electromagnetic radiation. Again, it is pointed out that by their "position", the position in z direction, or height, of the segments is referred to. In other words, changing the position of the segments changes their distance to the molding cavity.

As already discussed and explained above, adjusting the position of one or more of the segments, i.e., their distance from the molding cavity and thus generally also from the opposing electrode/capacitor plate, influences the field strength distribution of the radiated electromagnetic field within the molding cavity.

Additionally, the shape of the capacitor plate that is connected to the radiation source can also at least partially be adapted to the geometry of the part that is to be manufactured (i.e. the shoe sole or part of a shoe sole like a midsole or part thereof).

A fifth aspect of the present invention that goes hand in hand with the fourth aspect and that may also make use of, or rely on, any of the options, embodiments and examples disclosed in the context of the first, second and/or third aspect of the present invention, is a method for the manufacture of a shoe sole or part of a shoe sole from foam particles.

In an embodiment, the method comprises: a. ) loading the particles into a molding cavity of a molding tool which is formed from at least two molding halves which define the molding cavity, wherein at least two capacitor plates are arranged adjacent to the molding cavity, wherein at least one of the capacitor plates is connected to a radiation source, and wherein at least one of the capacitor plates comprises several segments that have an adaptable distance to the molding cavity; b. ) irradiating the molding cavity with electromagnetic radiation emitted by the capacitor plates; and c. ) locally adjusting a field strength distribution of the irradiating electromagnetic field within the molding cavity by modifying the adaptable distance of the segments to the molding cavity.

The modifying can occur before and/or during irradiation of the molding cavity with the electromagnetic radiation.

It is mentioned that such foam particles are also referred to in the art as particles of expanded material, an expanded material being a material that has already been foamed (compared to an expandable material, which can be foamed but has not yet been foamed). In other words, the particles have a core of foamed material already before being inserted into the mold.

Examples of how the invention can be implemented are explained in more detail below using the attached drawings. In addition, explicit reference is made to the published documents <CIT> and <CIT> and to the <CIT>, as well as to the published applications <CIT> and <CIT> owned by the applicant of the present application, in which apparatuses and methods are described in detail, which are further developed and improved by the aspects of the invention.

The included drawings show the following:.

A possible design of an apparatus <NUM> for the production of a particle foam part, in particular a shoe sole or a midsole or a part of a shoe sole/midsole, is shown in <FIG>. The apparatus <NUM> comprises a material container <NUM>, a molding tool <NUM> and a line <NUM> leading from the material container <NUM> to the molding tool <NUM>.

The material container <NUM> is used to hold loose foam particles. The material container <NUM> has a base <NUM>, and it is connected in the base <NUM> to a compressed air source <NUM> via a compressed air line <NUM>. The compressed air line <NUM> is connected to several nozzles (not shown) arranged in the base <NUM>, so that several air streams (= fluidizing air) can be introduced into the material container <NUM>, which swirl the foam particles contained therein around and thus separate them.

In the area of the base <NUM> of the material container <NUM> an opening is formed to which the conveying line <NUM> is connected. The opening can be closed by means of a slide valve (not shown).

Adjacent to the material container <NUM> there is a propelling nozzle <NUM> in the conveying line <NUM>, which is connected to the compressed air source <NUM> via a further compressed air line <NUM>. Compressed air supplied to this propelling nozzle <NUM> serves as transportation air, as it enters the conveyor line <NUM> through the propelling nozzle <NUM> and flows in the direction of the molding tool <NUM>. This creates a negative pressure at the propelling nozzle <NUM> on the side facing the material container <NUM>, which sucks foam particles out of the material container <NUM>.

The conveying line <NUM> leads to a filling injector <NUM>, which is coupled to the molding tool <NUM>. The filling injector <NUM> is connected to the compressed air source <NUM> via a further compressed air line <NUM>. The compressed air supplied to the filling injector <NUM> is used on the one hand to fill the molding tool <NUM> by applying the compressed air to the flow of foam particles in the direction of the molding tool <NUM>. On the other hand, the compressed air supplied to the filling injector <NUM> can also be used to blow back the foam particles from the conveying line <NUM> into the material container <NUM> when the filling process at the molding tool <NUM> is completed.

Molding tool <NUM> is formed from two molding halves <NUM>, <NUM>. Between the two molding halves <NUM>, <NUM> at least one molding cavity <NUM> is defined, into which the filling injector <NUM> opens for introducing the foam particles. The volume of the molding cavity <NUM> can be reduced by bringing the two molding halves <NUM>, <NUM> together. When the molding halves <NUM>, <NUM> are moved apart, a gap is formed between the molding halves <NUM>, <NUM>, which is known as the crack gap. For this reason, such a molding tool <NUM> is also referred to as a crack gap mold.

A respective capacitor plate <NUM>, <NUM> is arranged on each of the molding halves <NUM>, <NUM>. These capacitor plates <NUM>, <NUM> each consist of a material with good electrical conductivity, such as copper or aluminum. The filling injector <NUM> is located on the molding half <NUM>. The filling injector <NUM> extends through a recess in the capacitor plate <NUM>, which is mounted on the molding half <NUM>.

The two capacitor plates <NUM>, <NUM> are each formed from several segments <NUM>, <NUM>, which are arranged adjacent to each other and are electrically and mechanically connected to each other. The segments <NUM>, <NUM> are detachable from each other.

By adding or removing individual segments <NUM>, <NUM>, the size of the first capacitor plate <NUM> formed from the segments <NUM> and the size of the second capacitor plate <NUM> formed from the segments <NUM> can be adapted to the size of the molding tool <NUM>. In this way, different sized molding tools <NUM> can be arranged between the capacitor plates <NUM>, <NUM>. This makes it possible to generate electromagnetic radiation between the capacitor plates <NUM>, <NUM> specifically only in the area of molding cavity <NUM>. In areas where no electromagnetic radiation is required for welding foam particles, it is possible to avoid generating electromagnetic radiation by removing individual segments <NUM>, <NUM>.

The segments <NUM>, <NUM> are each attached to an insulator <NUM>, <NUM> and form two opposing segment arrangements. The insulators <NUM>, <NUM> are used to hold the segments <NUM>, <NUM> in place on two opposite sides of the molding tool <NUM>.

The insulators <NUM>, <NUM> with the segments <NUM> and <NUM> attached to them are mounted so that they can move relative to each other. This means that the molding halves <NUM>, <NUM> of molding tool <NUM> together with the segmented capacitor plates <NUM>, <NUM> which rest against the sides of the molding tool <NUM> can be moved towards and away from each other. Furthermore, it is possible to exchange the molding tool <NUM> when the segment arrangements <NUM>, <NUM> are moved apart.

As an option, segments <NUM>, <NUM> can also be attached to molding tool <NUM> in such a way that they can be detached from molding tool <NUM> and from each other. In this case both insulators <NUM>, <NUM>, or at least one of them, can be omitted.

One of the segments <NUM> is connected via an electrical line <NUM> to a generator <NUM> for the transmission of high-frequency voltages, which forms an AC voltage source. The electrical connection of the segments <NUM> to each other causes high-frequency voltages to be applied to them, thus forming the capacitor plate <NUM>.

The segments <NUM> on the opposite side of the molding half <NUM>, which form the capacitor plate <NUM>, are electrically connected to ground <NUM>, as is the generator <NUM>. As the segments <NUM> are also electrically connected to each other, only one of the segments is connected to ground <NUM>.

Generator <NUM> is a source of electromagnetic radiation. The generator is preferably designed to generate RF radiation. The generator can also be designed to generate microwave radiation. In the case of larger molding cavities <NUM>, RF radiation can be used to heat the molding tool <NUM> much more evenly than microwave radiation. In addition, most plastic materials can absorb RF radiation much better than microwave radiation. Therefore the use of RF radiation is preferred.

The molding halves <NUM>, <NUM> each have a base body, which can be formed from an electrically non-conductive and, in particular, for electromagnetic RF radiation essentially transparent material, such as polytetrafluoroethylene (PTFE), polyethylene (PE), in particular ultra-high molecular weight polyethylene (UHMWPE), polyether ketone (PEEK). Preferably, only the capacitor plates <NUM>, <NUM> are electrically conductive. The "essentially transparent material" is a material that can be penetrated by electromagnetic radiation, especially RF radiation. However, this material can be specifically designed with a certain absorption coefficient for electromagnetic RF radiation in order to convert part of the electrical RF radiation into heat and to heat the molding halves <NUM>, <NUM>. This is explained in more detail below.

The molding tool <NUM> can optionally be connected to a vacuum pump so that a vacuum can be applied to molding cavity <NUM>. This vacuum causes the moisture contained in molding cavity <NUM> to be extracted.

The capacitor plates <NUM>, <NUM> may be equipped with a cooling device. In the present example, the cooling device is provided by fans <NUM>, which direct cooling air to the side of the capacitor plates <NUM>, <NUM> facing away from the molding cavity <NUM>. Cooling fins can be provided to increase the cooling effect.

Alternatively or additionally, cooling lines can also be arranged on the capacitor plates <NUM>, <NUM>, through which a cooling medium is passed. The preferred cooling medium is a liquid, such as water or oil.

The apparatus <NUM> can also be designed with a steam generator and a steam supply to the molding cavity <NUM> and/or to the conveying line <NUM> to supply saturated dry steam to the molding cavity <NUM> for heating the foam particles and/or to wet foam particles during their transportation from the material container <NUM> to the molding cavity <NUM>. It is also possible to wet the foam particles, which are located in the material container <NUM>, with water in liquid form. For this purpose, corresponding nozzles may arranged in the material container <NUM>, which vaporize the water.

To illustrate further details of the apparatus <NUM>, <FIG> schematically shows an enlarged partial view of the apparatus <NUM> as a sectional view, but in this example, unlike the example shown in <FIG>, each of the segments <NUM> of the second capacitor plate is connected to ground <NUM>, as a further option. In all other respects, the explanations given in <FIG> also apply to <FIG> and vice versa, with similar elements in the figures having the same reference numerals.

Fasteners <NUM>, which are preferably designed as screws, are used for detachable fastening of segments <NUM>, <NUM> to the respective insulator <NUM> or <NUM>.

Electrically conductive connecting elements <NUM>, which are designed as electrically conductive, flexible metal elements in the form of foils, for example copper or brass foils, serve to electrically connect the segments <NUM> to each other, which are arranged next to each other and form the first capacitor plate <NUM>.

The connecting elements <NUM> electrically connect two or more adjacent segments <NUM> at their edges. When fastening the segments <NUM> to the insulator <NUM>, the electrically conductive connecting elements <NUM> are pressed against the edges of the segments <NUM>. This creates an electrical connection between its segments <NUM> for the capacitor plate <NUM>.

In the example shown here, on the second capacitor plate <NUM> the connecting elements <NUM> are not absolutely necessary due to the grounding of the individual segments <NUM> on the plate <NUM>, but they can optionally be provided and arranged here in the same way as for the first capacitor plate <NUM>.

By contrast, in the example shown in <FIG>, they are provided on both capacitor plates <NUM>, <NUM>, since only one of the segments <NUM> of capacitor plate <NUM> is connected to ground <NUM>.

The electrical line <NUM>, designed as a high frequency line, connects one of the segments <NUM> with the generator <NUM> (see <FIG>). The segment electrically connected to the generator <NUM> is designed as high frequency connection segment or generator connection segment <NUM>. Due to the electrical connection between the adjacent segments <NUM>, the entire segment arrangement <NUM> is electrically connected to the generator <NUM> and forms the first capacitor plate <NUM>.

In this way, the segments <NUM> form a capacitor plate set <NUM>, which combined make it possible to form the first capacitor plate <NUM>, which can be connected to an RF radiation source and whose size can be adapted to the size of the molding tool <NUM>. The capacitor plate <NUM> can also be adapted to the dimensions of mold cavity <NUM> within mold <NUM>.

Segment <NUM>, which is designed as an RF connection segment and includes a connection area for line <NUM> for connection to generator <NUM>, forms a first capacitor plate segment of capacitor plate set <NUM>.

The other segments <NUM> form second capacitor plate segments for forming the capacitor plate <NUM>, i.e. the first capacitor plate segment <NUM> and at least one of the second capacitor plate segments <NUM> are designed to together form the capacitor plate <NUM> and form the capacitor plate set <NUM>. The area of the capacitor plate <NUM> that can be produced by the capacitor plate set <NUM> can be adapted to the size of the molding tool <NUM> for the production of a particle foam part, e.g. a shoe sole or midsole or part thereof.

The first capacitor plate segment <NUM> and the second capacitor plate segments <NUM> are designed to be fastened to the insulator <NUM> using fasteners <NUM>.

The segments <NUM> of the second capacitor plate <NUM> arranged opposite the first capacitor plate <NUM> form further capacitor plate segments of the capacitor plate set <NUM>. The further capacitor plate segments <NUM> complement the capacitor plate set <NUM> by enabling the production of a second capacitor plate <NUM> and thus allow the formation of a complete capacitor (from the first and second capacitor plates <NUM>, <NUM>). They are designed for mounting on the insulator <NUM>.

Both insulators <NUM>, <NUM> can be components of the capacitor plate set <NUM>.

In the example shown here, a press <NUM> is also shown, which is connected via a cylinder-piston unit <NUM> to the insulator <NUM>, which is located on one side of the molding tool <NUM>. The insulator <NUM>, which is located on the opposite side of the molding tool <NUM>, is stationary, so that the molding tool <NUM> can be pressed together between the two capacitor plates <NUM>, <NUM>, which are attached to the insulators <NUM>, <NUM> on the side facing the molding tool <NUM>.

As a result, the foam particles located in molding cavity <NUM> of molding tool <NUM>, which is designed as a crack gap mold, can be compressed during their exposure to the electromagnetic radiation. In this way, the foam particles are not only pressed together due to their thermal expansion as a result of the electromagnetic heating, but also by mechanically pressing together the two molding halves <NUM>, <NUM> of the molding tool <NUM>.

<FIG> shows another possible way of connecting adjacent segments <NUM> and <NUM> of the capacitor plates <NUM> and <NUM>, as they are shown in <FIG> and <FIG> and also in further embodiments that will follow. The segments <NUM>, <NUM> each have edge areas <NUM> protruding from the segment body at their edges, which are designed in such a way that they interlock when the segments <NUM>, <NUM> are joined together. The edge areas <NUM> form a stepped seam at the joints of the segments <NUM>, <NUM>. In this way, a particularly reliable electrical and mechanical connection between the segments <NUM>, <NUM> is created, which can also be achieved very cost-effectively.

<FIG> shows an example of an arrangement of the segments <NUM>, <NUM>, which form the capacitor plate <NUM> and the capacitor plate <NUM>, respectively, and can be produced by the capacitor plate set <NUM>. The figure shows a view of the surface of the capacitor plate.

In this arrangement, a central segment <NUM> is arranged centrally and surrounded by additional segments <NUM>. The central segment <NUM> has a square shape. The additional segments <NUM> each extend along one side of the central segment to <NUM> and along one side of another additional segment.

In the example shown here, a first additional segment <NUM> is provided in addition to the central segment <NUM>, which extends along one of the sides of the square. A second additional segment <NUM> is provided which extends along another side of the square and along one side of the first additional segment <NUM>, a third additional segment <NUM> is provided which extends along another side of the square and along the second additional segment <NUM>, and a fourth additional segment <NUM> is provided which extends along the remaining side of the square and along two sides of the additional segments <NUM>.

In this way, different rectangles can be formed by combining several segments <NUM>, <NUM> as capacitor plate surfaces. In addition, further additional segments can be provided to complete the arrangement or to surround it in the manner of a further ring of segments. The central segment <NUM> can also be formed as a rectangle.

In addition to rectangles and squares, other different dimensions, shapes and geometries of the segments <NUM>, <NUM> are also possible and capacitor plates can thus be obtained in a wide variety of shapes.

In the following, further embodiments of the invention are explained on the basis of <FIG>, wherein identical, similar or functionally equivalent elements are again marked with the same reference signs as in the preceding figures, and have already been explained above.

The molding tool <NUM> of the apparatus <NUM> according to <FIG> is formed by two molding halves <NUM>, <NUM>, each of which has a base body made of an electrically non-conductive material that is transparent, especially to electromagnetic RF radiation. This material is PTFE, PE, PEEK or another material transparent to RF radiation. The molding halves <NUM>, <NUM> define a molding cavity <NUM>. In the present design example, molding cavity <NUM> has inner boundary surfaces <NUM>, which have a contoured shape deviating from a flat surface.

The molding halves <NUM>, <NUM> each have a flat outer surface <NUM>, on which a capacitor plate <NUM>, <NUM> is arranged. The space between the contoured boundary surfaces <NUM> and the outer surfaces <NUM> is filled with material that is transparent to electromagnetic radiation.

With this molding tool <NUM>, three-dimensionally contoured particle foam parts can be produced, whereby the shape of the particle foam part is defined by the inner boundary surfaces <NUM> of the molding halves <NUM>, <NUM>. Such a molding tool <NUM> is suitable, e.g., for producing small particle foam parts with a substantially uniform density. It can also be used for the production of a shoe sole or midsole or part thereof.

The capacitor plates <NUM>, <NUM> are flat and are designed as described above with reference to <FIG>. The first capacitor plate <NUM> is formed by adjacent segments <NUM>. The second capacitor plate <NUM> is also made up of adjacent segments <NUM>.

Each of the collection of segments <NUM> and <NUM> is attached to an insulator <NUM> and <NUM>, respectively, with fasteners <NUM>, whereby the segments <NUM> of the first capacitor plate <NUM> are mechanically and electrically conductive, detachably connected to each other as explained above with reference to <FIG>. Likewise, the segments <NUM> of the second capacitor plate <NUM> are mechanically and electrically conductive and detachably connected to each other.

The segments <NUM>, <NUM> and optionally also the insulators <NUM>, <NUM> are components of a capacitor plate set <NUM> as described above.

The problem with large or thicker particle foam parts is that they heat up more in the middle than at the edges, which can destroy the particle structure. To avoid an uneven heating of the central area and the edge area of a particle foam part, the molding tool <NUM> can be tempered and/or additional heat can be added to the foam particles within molding cavity <NUM>, e.g. at the edge area, as described in <CIT>.

By a modification of the depicted apparatus <NUM> which will be explained in more detail below, it is possible to switch off individual segments <NUM>, <NUM> even before the end of the welding process, to prevent overheating of the foam particles located between the respective segments.

The embodiments discussed above each have flat capacitor plates <NUM>, <NUM>. In another embodiment, the molding tools <NUM> can be designed in such a way that the capacitor plates <NUM>, <NUM> are adapted to the shape of the particle foam part to be produced or the molding cavity <NUM>. This can be beneficial, for example, for the production of shoe soles or midsole or parts therefore with a complex three-dimensional geometry, to promote an even welding of the foam particles throughout the component.

The embodiment of the apparatus <NUM> shown in <FIG> has two molding halves <NUM>, <NUM>, which by their inner boundary surfaces <NUM> define a step-shaped molding cavity <NUM>. The outer surfaces <NUM> of the molding halves <NUM>, <NUM> are adapted to the contour of the corresponding inner boundary surfaces <NUM> of the respective molding half <NUM>, <NUM>. In other words, the inner boundary surfaces <NUM> are mapped to the respective outer surfaces <NUM> of the mold halves <NUM>, <NUM>, and the molding tool <NUM> can hence be formed with a uniform thickness from the outer surface <NUM> to the inner boundary surface <NUM>. On the outer surface <NUM>, preferably small structures of the inner boundary surface <NUM> are smoothed out.

Molding tool <NUM> thus has two contoured molding halves <NUM>, <NUM>, and against their outer surfaces <NUM> a correspondingly contoured, respective segmented capacitor plate <NUM>, <NUM> rests, which is formed from several segments <NUM> or <NUM> and is otherwise designed as described above with reference to <FIG>.

Such an adaptation of the shape of the capacitor plates with segments <NUM>, <NUM> to the shape of the particle foam parts to be produced is particularly useful for shell-shaped particle foam parts (e.g., boxes or bowls with spherically shaped segments), or, as already mentioned above, for shoe soles or midsoles or parts therefore.

Also in the example shown here, insulators <NUM>, <NUM> are used to hold the segments <NUM>, <NUM> in place. The sides of the insulators facing the molding halves are adapted to the shape of the outer surfaces <NUM> of the molding halves <NUM>, <NUM>.

<FIG> shows another embodiment, in which the first capacitor plate <NUM> formed from segments <NUM> together with the insulator <NUM> and the pressing tool formed by the press <NUM> and the cylinder-piston unit <NUM> is generally provided as described above with reference to <FIG>. Reference is made in particular to <FIG> and the related description.

In this embodiment, molding tool <NUM> has a first molding half <NUM> and a second molding half <NUM>, which form a molding cavity <NUM> between them, in which foam particles <NUM> to be welded are located. In addition to the description of molding tool <NUM> that now follows, reference is also made to the <CIT>, in which further details of molding tool <NUM> are explained.

The second molding half <NUM> or at least a part of it is electrically conductive or made of electrically conductive material. The molding tool <NUM> can be used as part of the apparatus <NUM>, wherein the second molding half <NUM> serves as a second capacitor plate and is electrically connected to ground <NUM> for this purpose.

The second molding half <NUM> has a base body <NUM> made of an electrically conductive material. This base body <NUM> consists of aluminum, copper or an alloy with good electrical conductivity, for example. It is optionally provided with an electrically insulating coating <NUM> and forms a bottom wall <NUM>. The electrically conductive base body <NUM> has an electrical connection to be connected to the generator <NUM> or to ground <NUM>.

The generator <NUM> (see <FIG>, <FIG> and <FIG>), which is electrically connected to the segmented capacitor plate <NUM> by the high-frequency line <NUM>, generates electromagnetic waves or an electrical alternating voltage with respect to ground potential <NUM>, which is applied to the base body <NUM> of the second molding half <NUM>. This creates an electromagnetic alternating field, especially RF radiation, in the molding cavity <NUM> between the segmented capacitor plate <NUM> and the base body <NUM>.

A circumferential side wall <NUM> of the second molding half <NUM> is formed from an electrically non-conductive material, in particular from a plastic material, and extends from the bottom wall <NUM> and starting on the sides of the molding half <NUM> in the direction of the first molding half <NUM>, such that the molding cavity <NUM> is laterally limited.

However, it is also possible that both the bottom wall <NUM> and the side wall <NUM> are formed by the electrically conductive base body <NUM>. However, it is important that there is no electrically conductive connection between the two molding halves <NUM>, <NUM>.

The first molding half <NUM>, which is located on the side of molding tool <NUM> facing the segmented capacitor plate <NUM>, is made of an electrically non-insulating material as described above.

The first molding half <NUM> forms a plunger which can enter the cavity formed by the second molding half <NUM>, thus sealing the molding cavity <NUM>. The tight seal between the two molding halves <NUM>, <NUM> is at least tight enough to prevent foam particles <NUM> from escaping. Molding cavity <NUM> is not necessarily sealed gas-tight, however.

The first molding half <NUM> has an inner boundary wall <NUM>, which is contoured and defines molding cavity <NUM>. Starting from the boundary wall <NUM>, several partitions <NUM> extend in the direction of the first capacitor plate <NUM> towards an optional cover element <NUM>. The partitions <NUM> serve to support the boundary wall <NUM>. Cavities <NUM> are formed between the partitions <NUM> in the first half of the mold <NUM>, which considerably reduce its mass.

This leads to a beneficial reduction of the influence on the electromagnetic field strength in molding cavity <NUM>, which considerably improves the flexibility in the use and shaping of the molding cavity <NUM> as well as the plunger molding half <NUM>.

Furthermore, the cavities <NUM> can be used to trim the plunger mold half <NUM> to influence the electromagnetic field in the mold cavity <NUM>, in addition to the flexibility achieved by changing or adjusting the surface of the capacitor plate <NUM> by different combinations of segments <NUM>. Trimming can also be used to achieve a particularly uniform or even distribution of the field strength in the molding cavity <NUM>.

Trim bodies made of a dielectric material (not shown in the figure) can also be inserted into the cavities <NUM>. Due to the polarizing properties of a dielectric, the electromagnetic alternating field is concentrated by the dielectric lying in the path of the field lines in the adjacent region of the molding cavity <NUM>. In regions along the path of the same field line which are kept vacant by the dielectric, the field is not concentrated in the adjacent region of the molding cavity <NUM>, such that the field is weaker in this region of the molding cavity <NUM> than in a region of the molding cavity <NUM> that is adjacent to a dielectric. By using trimming bodies of different size, shape and permittivity, the electric field can thus be additionally influenced in different ways. The permittivity of a dielectric is greater than that of vacuum or air.

All these measures additionally contribute to the fact that the electromagnetic field is especially targeted, which results in an even further increased effectiveness of the disclosed apparatus and promotes an even welding of the particles throughout the component, also for complex geometries as encountered with, e.g., shoe soles or midsoles or parts thereof.

The two molding halves <NUM>, <NUM> can be moved relative to each other by means of a press <NUM>, and a predetermined force can be applied to them. For this purpose, the press <NUM> is connected via a cylinder-piston unit <NUM> to the insulator <NUM>, to which the first capacitor plate <NUM> formed by the segments <NUM> is attached, as described above with reference to <FIG>. To press the two molding halves <NUM>, <NUM> together, the first molding half <NUM> is moved by the movable segmented capacitor plate <NUM> in the direction of the second molding half <NUM> by means of the press <NUM>.

On the second molding half <NUM> there is a through-hole for feeding the foam particles <NUM>, which is referred to as the filling opening <NUM>. A filling injector <NUM> (see <FIG>) is connected to the filling opening <NUM>. The filling injector <NUM> differs from conventional filling injectors in that it does not have a closing mechanism for closing the filling opening <NUM>, as explained in more detail below.

The first molding half <NUM> has one or more through-holes (not shown in the figure) to allow air to escape.

The filling opening <NUM> and the venting openings are arranged on a section or area, in particular an edge area, of the second molding half <NUM>, which is covered by the first molding half <NUM> when the molding tool <NUM> is closed. As a result, the filling opening <NUM> and the venting opening are automatically closed when the molding tool <NUM> is closed by inserting the first molding half <NUM> into the cavity formed by the second molding half <NUM>. This means that it is not necessary for the filling injector <NUM> to have a closing mechanism with which the filling opening <NUM> is closed.

Because the molding halves <NUM>, <NUM> both delimit the molding cavity <NUM> and at the same time form one of the capacitor plates, the distance between the "capacitor plates" and the molding cavity <NUM> is very small. As a result, the losses of electromagnetic radiation are very low, which means that the proportion of power that is introduced as heat into the foam particles <NUM> to be welded is very high. Such a tool thus permits very efficient welding of the foam particles <NUM> to form a particle foam part.

<FIG> shows an apparatus <NUM> for producing a particle foam part according to another embodiment, in which, similar to <FIG>, the second molding half <NUM> is formed from electrically conductive material and is connected to ground potential <NUM>, thereby serving as a second capacitor plate.

The first molding half <NUM> is electrically non-conductive and, as in the version shown in <FIG>, comprises a boundary wall <NUM>, which is contoured and is firmly connected to a cover element <NUM> by partitions <NUM>. Here, too, cavities <NUM> are formed between the partitions <NUM> to influence the electromagnetic field in the molding cavity <NUM> between the two molding halves <NUM>, <NUM>, as explained in detail above.

In contrast to the embodiment shown in <FIG>, the circumferential side wall <NUM>, which closes off the molding cavity <NUM> at the sides, is formed on the first molding half <NUM>. Within the side wall <NUM>, a part <NUM> of the electrically conductive second mold half <NUM> protrudes into in the molding cavity <NUM> formed by the circumferential side wall and closes the mold cavity <NUM> on this side, while it is closed on the opposite side by the boundary wall <NUM> of the first mold half <NUM>.

The foam particles <NUM>, which are located in molding cavity <NUM>, are compressed by the protruding part <NUM> when the two molding halves <NUM>, <NUM> are pressed together by the segmented capacitor plate <NUM> being pressed towards the first molding half <NUM> by means of the press <NUM>.

A filling opening <NUM> for filling the foam particles <NUM>, which leads into the molding cavity <NUM>, is opened by moving the two molding halves <NUM>, <NUM> apart and closed by moving the two molding halves <NUM>, <NUM> towards each other, as described above including with further details with reference to <FIG>.

<FIG> shows another embodiment of the invention in which the segments of the capacitor plates are electrically insulated from each other.

In the apparatus <NUM> shown here, the segments <NUM> of the first capacitor plate <NUM> formed by them are permanently attached to the insulator <NUM>, electrically insulated from each other, with each segment being separately connected to the generator <NUM> via a tunable resonant circuit <NUM>. The generator <NUM> is connected to ground potential <NUM>.

The segments <NUM>, which form the second capacitor plate <NUM>, are electrically connected to ground <NUM>, as is the generator <NUM>. The segments <NUM> are permanently attached to the insulator <NUM>. If, as in the case shown here, all segments <NUM> are connected to ground, it is not absolutely necessary to arrange the segments <NUM> electrically isolated from each other. It is also possible to make the second capacitor plate <NUM> continuous or not segmented or divided into segments and to connect it electrically to ground <NUM>.

In case the segments <NUM> of the second capacitor plate <NUM> are electrically isolated from each other, the generator <NUM> can be connected to each of the segments <NUM> instead of to ground <NUM>, in which case the segments <NUM> are not connected to ground <NUM>.

As described above with reference to <FIG>, the isolator <NUM> is mechanically connected to a press tool, which is formed by a press <NUM> and a cylinder-piston unit <NUM>. This allows the insulator <NUM> with the segments <NUM> of the first capacitor plate <NUM> attached to it to be pushed towards the second capacitor plate <NUM>, which is located opposite, so that a pressing force is exerted from both sides on the molding tool <NUM>, which is located between the two capacitor plates <NUM> and <NUM> for welding foam particles arranged therein.

The insulators <NUM>, <NUM> and the segments <NUM>, <NUM>, as well as the tunable resonant circuits <NUM> form a capacitor plate set <NUM>. The segments <NUM>, <NUM> are designed as capacitor plate segments and can be designed as in the above described versions and embodiments. They can also have a geometry and form a two-dimensional arrangement as described above.

Molding tool <NUM> can be designed as in one of the above described versions and embodiments. Small modifications may be necessary to arrange the capacitor plates <NUM>, <NUM> according to <FIG>.

<FIG> are used below to explain the operation of the device shown in <FIG>. <FIG> schematically shows a simplified equivalent circuit diagram of the device according to <FIG>.

<FIG> shows a single device for controlling the electrical power supplied to segment pairs <NUM>, <NUM> in a schematic simplified circuit diagram. In particular, <FIG> shows schematically in an electrical circuit diagram the generator <NUM> and the partial capacitor formed by the segments <NUM>, <NUM>, which encloses the molding halves <NUM>, <NUM>, and a connection line (hollow waveguide or coaxial line) <NUM> suitable for transmitting the electromagnetic waves, with which the electromagnetic waves are transmitted from the generator <NUM> to the molding partial capacitor <NUM>, <NUM>. The hollow waveguide forming the connection line <NUM> is preferably designed as a coaxial air line with an electrically conductive inner tube and an electrically conductive outer tube. The coaxial air line is dimensioned so that high voltage signals can be reliably transmitted. The characteristic impedance is preferably set to about <NUM>Ω.

In this connection line <NUM> a generator-sided inductance <NUM> and a tool-sided inductance <NUM> are symbolically indicated. These inductances are caused by the line itself, whereby the length of the respective line sections determine the value of the respective inductance. A tool-sided capacitor <NUM> is connected in parallel with the respective tool sub-capacitor <NUM>, <NUM>. This capacitor <NUM> represents the electrical capacitance between the capacitor segment <NUM> and the housing <NUM> of the molding tool <NUM>. The tool capacitor <NUM>, <NUM>, the capacitor <NUM> and the tool-sided inductor <NUM> form a tool resonant circuit <NUM>.

A generator-sided capacitor <NUM> is connected in series with generator <NUM> and the generator-sided inductance. The generator-sided capacitor <NUM> and the generator-sided inductance <NUM> form a generator resonant circuit <NUM>. At least the generator-sided capacitor <NUM> or the generator-sided inductance <NUM> is provided variably, for example by using a capacitor with capacitor plates that can be spaced apart or by providing connection line sections of different lengths. It is also possible that both the generator-sided capacitor <NUM> and the generator-sided inductance <NUM> are variable. The generator-sided capacitor <NUM> can be equipped with a servomotor, which, when actuated, changes the distance between the two capacitor plates, for example by moving one of the two capacitor plates in a straight line, such that both capacitor plates are always parallel to each other, or by swiveling one of the two capacitor plates.

By changing the capacity of the capacitor <NUM> or the inductance <NUM>, the resonance frequency of the generator resonant circuit <NUM> can be changed or tuned. If the resonant frequencies of the generator resonant circuit and the tool resonant circuit match, the maximum electrical power is transmitted from the generator <NUM> to the tool resonant circuit <NUM> and thus to the tool sub-capacitor (or partial capacitor) <NUM>, <NUM>. By changing the resonant frequency of the generator resonant circuit <NUM>, the transmission of the electrical power can be controlled in a targeted manner, wherein the more the resonant frequencies of the two resonant circuits <NUM>, <NUM> differ, the lower the transmitted power. The tuning of the generator resonant circuit <NUM> can thus be used to specifically adjust the electrical power introduced into the molding cavity <NUM>.

In the present embodiment, the resonant frequency of the generator resonant circuit <NUM> is changed. It is equally possible to change the resonant frequency of the tool resonant circuit <NUM>. This has the same effect with regard to the transmission of the electrical power. However, it is more difficult to provide a variable capacitor or a variable inductance on the tool side than on the generator side.

The segments <NUM>, <NUM> thus each form a tool capacitor or tool sub-capacitor or tool partial capacitor, which is separately connected to the generator <NUM> via its own tunable resonant circuit <NUM>. The resonant circuit <NUM> thus comprises the tool resonant circuit <NUM> as well as the generator resonant circuit <NUM>. By tuning the two resonant circuits <NUM>, <NUM>, the tool capacitors <NUM>, <NUM> can be separated from the generator <NUM> individually or in groups by changing the resonant frequency, so that no power or hardly any power is transmitted to them. In this way, they can be switched on or off from the radiation-emitting arrangement of capacitor plate segments <NUM>, <NUM>, by changing the resonant frequency of one (or both) of the two resonant circuits <NUM>, <NUM>.

The resonant circuit <NUM> thus forms a switching device <NUM> for connecting or disconnecting a capacitor plate segment <NUM> to or from the capacitor plate <NUM>, or capacitor plate segment <NUM> to or from the capacitor plate <NUM>, respectively. The segments <NUM>, <NUM> can be connected or disconnected individually or in groups as partial capacitors to form the capacitor <NUM>, <NUM>.

This means that the electromagnetic radiation source <NUM> is part of a generator resonant circuit <NUM>, while any connection lines for guiding the electromagnetic waves together with a respective pair of segments <NUM>, <NUM> that form a partial capacitor form a tool resonant circuit <NUM>. By changing an inductance or a capacitance, the tool resonant circuit <NUM> can be tuned in its resonant frequency and forms a tunable resonant circuit.

In other words, the regulating or control device for controlling the tunable resonant circuit can be designed in such a way that the power supply from the generator resonant circuit to the tool resonant circuit is switched on or off or interrupted by its tuning, wherein (at least) one of the two resonant circuits is provided as a tunable resonant circuit. In this way, the segment(s) in question is added to or removed from the capacitor plate that is formed from several such segments and which applies electromagnetic radiation to the molding tool during the welding process.

By controlling the energy supply on the individual lines, it is possible to set and control which segments <NUM> of capacitor plate <NUM> (and/or segments of <NUM> of the capacitor plate <NUM>) are operated and which are not. By switching individual segments on and off by means of resonant circuit tuning, the size of the capacitor plates <NUM>, <NUM> can be adapted to the size of the molding tool <NUM> with regard to its radiation-emitting surface. This means that it is not necessary to mechanically remove or attach individual segments <NUM>, <NUM> depending on the molding tool <NUM> in order to adapt the surface of the capacitor plates <NUM>, <NUM>. It is also not necessary to mechanically interrupt or mechanically switch the connection lines <NUM> between the generator <NUM> and the individual segments <NUM>, <NUM>.

For further details we refer to the already mentioned publication <CIT>, which describes the circuit for tuning in more detail.

<FIG> shows a device for controlling the electrical power supplied to the tool capacitor <NUM>, <NUM> in a schematically simplified circuit diagram. The generator <NUM> is connected to the tool capacitor <NUM>, <NUM>. A measuring capacitor <NUM> is connected in parallel to the tool capacitor <NUM>, <NUM>. Its electrical capacitance is a fraction of the electrical capacitance of the tool capacitor <NUM>, <NUM>. The measuring capacitor <NUM> is connected via a coaxial line <NUM> to a voltage measuring device (voltmeter) <NUM>. Preferably, a diode <NUM> is connected in parallel with the measuring capacitor <NUM>. The coaxial line <NUM> is connected in series with an inductor <NUM>, which is used to filter high-frequency signals.

The measuring unit consisting of the measuring capacitor <NUM> and the diode <NUM> is separated from the tool capacitor <NUM>, <NUM> by an isolating capacitor <NUM>. The isolating capacitor has a high dielectric strength. The capacitance of the isolating capacitor <NUM> is smaller than the capacitance of the measuring capacitor <NUM>, which means that a higher voltage drop occurs across the isolating capacitor <NUM> than across the measuring capacitor <NUM>. The ratio of the capacitance of the isolating capacitor <NUM> to the capacitance of the measuring capacitor <NUM> is preferably <NUM>:<NUM> or <NUM>:<NUM> or <NUM>:<NUM>. As a result, the voltage applied to tool capacitor <NUM>, <NUM> is reduced in the measuring unit <NUM>, <NUM> in such a way that it lies within a measuring range of the voltage measuring device <NUM> and can be reliably detected by the latter.

With this circuit, a voltage drop occurs at measuring capacitor <NUM> which corresponds to the voltage applied to tool capacitor <NUM>, <NUM> and is reduced according to the ratio of the capacitance of measuring capacitor <NUM> to the capacitance of isolating capacitor <NUM>. By providing diode <NUM>, only the oscillation halves of a certain polarity are generated. The diode <NUM> thus forms a rectifier of the voltage occurring at measuring capacitor <NUM>. This measuring voltage is measured with the voltage measuring device <NUM> and converted into a measuring signal. The measuring signal is forwarded to a control device <NUM> which automatically controls the generator <NUM> to deliver a predetermined electrical power, in order to generate a specific voltage on the tool capacitor or a specific measuring voltage on the measuring capacitor, which is a fraction of the voltage on the tool capacitor.

The device shown in <FIG> can be further provided in such a manner that for several or all pairs of segments <NUM>, <NUM> a device for controlling the electrical power supplied to the capacitor formed by the respective pair of segments <NUM>, <NUM> is provided in accordance with <FIG>. This allows the power of each respective pair of segments <NUM>, <NUM> to be controlled individually and the effective size of the tool capacitor to be set without the need for any moving parts. No calibration of the resonant circuits (generator resonant circuit, tool resonant circuit) is necessary either, since the actual power or voltage supplied to the respective segment pair <NUM>, <NUM> can be measured in a closed control loop and individually adjusted for the individual segment pair <NUM>, <NUM>.

An example of a process for manufacturing a particle foam part, like for example a shoe sole or a midsole or a part thereof, is described below with reference to the embodiment of <FIG>. Foam particles are filled into a molding cavity <NUM> of a molding tool <NUM>. Adjacent to the mold cavity <NUM>, two capacitor plates <NUM>, <NUM> are arranged, which are electrically connected to a radiation source <NUM> for electromagnetic radiation and generate electromagnetic radiation.

Capacitor plates <NUM>, <NUM> or at least one of them is formed by several segments <NUM>, <NUM>. The area of the capacitor plate <NUM>, <NUM> is adapted to the size of the molding tool <NUM> by combining a suitable number of radiation generating segments <NUM> and/or <NUM>.

The foam particles are welded together by the electromagnetic radiation between the capacitor plates <NUM>, <NUM>. The foam particles are heated in molding tool <NUM> by the electromagnetic radiation, i.e. heat is supplied to the foam particles by means of electromagnetic RF radiation. This welds them together to form a particle foam part.

Afterwards, the produced particle foam part is demolded and removed from the molding tool.

According to a preferred example, the segments <NUM>, <NUM> are detachably connected electrically and mechanically in order to combine them. In a modification as shown in <FIG>, the segments <NUM>, <NUM> are arranged electrically insulated from each other. By tuning an resonant circuit <NUM> connected to the respective segment, the segments <NUM>, <NUM> are switched on or activated, or switched off or deactivated, in the capacitor plate <NUM>, <NUM>. In this way, they are combined with each other depending on the size and geometry of the molding tool <NUM>.

This allows the surface of the capacitor plate <NUM>, <NUM>, which emits electromagnetic radiation, to be adapted to different molding tools <NUM>. As a result, it is not necessary to mechanically remove or mechanically add segments <NUM>, <NUM> when changing the molding tool <NUM>. Mechanical separation or connection of segments to the radiation source <NUM> to adapt the surface of the capacitor plates to the molding tool <NUM> is not necessary. This means that different molding tools <NUM> (e.g., corresponding to different sole or midsole sizes, or to different sole or midsole constructions) can be electromagnetically irradiated one after the other in a very short period of time.

To carry out the procedure, for example, one of the apparatuses is used as shown in <FIG> in different versions and embodiments or as discussed at other positions in this disclosure. Also, a capacitor plate set <NUM> as described above can be used to carry out the manufacturing process.

<FIG>-f show (part of) an apparatus <NUM> with a capacitor plate <NUM> that comprises several segments <NUM> that have an adaptable distance d to the molding cavity <NUM>, as well as corresponding measurement results obtained from a number of test runs on such an apparatus <NUM>.

The general construction of the apparatus <NUM> can be of the same or similar design as any of the other apparatuses (in particular, embodiments of the apparatus <NUM>) discussed herein so far. All of the options, embodiments, modifications and features already discussed can therefore also be used in, or combined with, that apparatus <NUM> that will now be described in relation to <FIG>-f (as far as physically and technically possible, of course). This compatibility between the different disclosed aspects and embodiments is also borne out by the fact that the same reference signs as above will also be used for functionally identical or at least functionally similar or equivalent elements and components.

The disclosed apparatus <NUM> can, in particular, be used for the production of a particle foam part, particularly a shoe sole or part of a shoe sole (e.g., a midsole or part thereof). It comprises a molding tool <NUM> which is formed from (at least two) molding halves <NUM> and <NUM>. The molding tool <NUM> defines a molding cavity <NUM>, which is bounded by the two molding halves <NUM> and <NUM> (s. , in particular, <FIG>). Into the molding cavity <NUM>, particles <NUM> of foamed or expanded material are loaded (e.g., particles of eTPU, or one of the further materials mentioned in this regard herein) and then welded or fused together (predominately at their surfaces, so that the interior foam structure is maintained, s. <FIG>), to form the molded part.

The apparatus further comprises (at least two) capacitor plates <NUM> and <NUM> which are arranged adjacent to the molding cavity <NUM>. "Adjacent" here means that the two capacitor plates <NUM> and <NUM> are arranged on two opposing sides of, and include the molding cavity <NUM> in between them, in such a manner that electromagnetic radiation emitted by the capacitor plates <NUM> and <NUM> floods the molding cavity <NUM> and leads to the desired welding of the foam particles <NUM>.

One of the capacitor plates, here the first capacitor plate <NUM>, is connected to a radiation source (not shown). The other capacitor plate, here the second capacitor plate <NUM>, comprises several segments <NUM> that have an adaptable distance d to the molding cavity <NUM>, i.e. their position along the z-direction (which is indicated in <FIG> and <FIG>) can be changed, such that the distance d of the radiation-emitting surface of a respective segment <NUM> from the molding cavity (measured, e.g., with regard to a wall of the molding cavity <NUM> or a specific point of refence within the molding cavity <NUM>) also changes. Consequently, the distance between the two capacitor plates <NUM> and <NUM> also changes locally by an adjustment of the position of a segment <NUM>. The distance d of the segments <NUM> to the molding cavity <NUM> can be individually adjusted by mechanical and/or electrical actuator means (e.g., by hand, or by a wrench, or by an electrical motor or a linear actuator, or by a gear driven by a motor, etc., depending on the specific design of the segments <NUM>).

For one of the segments, indicated as segment 86a in <FIG>, the distance to the molding cavity <NUM> is indicated as d, and the distance to the opposing capacitor plate <NUM> is indicated as D. Both these values change if the position of the segment 86a in the z-direction is changed.

The segments <NUM> are electrically connected to an electrically conductive electrode main body <NUM>, which in the embodiment shown and discussed here is on ground potential and is provided as a metal block. However, in other cases it may be connected to the radiation generator instead, and the opposing capacitor plate may be grounded. Aluminum is one option, because it is of comparably low weight and can be easily processed.

In the case shown in <FIG>-f, the segments <NUM> are provided as screws (e.g., pins are also possible, however) adjustably connected to the electrode main body <NUM>. The screws <NUM> here are metal screws that are screwed into corresponding threads provided in the electrode main body <NUM>.

While in <FIG>-f all screws <NUM> are of the same type and size and have the same head size this is not the rule, and the type, length, thickness and head size of the screws <NUM> may also change across the electrode/capacitor plate <NUM>. For example, smaller screws or screw heads may be used in regions where there are more screws per unit area, i.e., regions of the electrode/capacitor plate <NUM> where the density of segments <NUM> is higher (not shown in the figures; in <FIG>-f the density of the segments/screws <NUM> is constant across the capacitor plate <NUM>, apart maybe from the edges of the plate).

The segments/screws <NUM> are arranged in a two-dimensional grid, namely a quadratic grid in the embodiment of <FIG>-f. This grid is indicated by dashed lines <NUM> in <FIG>. Other kinds of grids are also possible, e.g., rectangular, triangular or hexagonal grids, or "mixed-type" grids comprising different geometrical shapes. The grid density (i.e., the number of adjustable segments/screws <NUM> per unit area) can also vary locally, as already explained above, even though this is not shown in <FIG>-f.

To allow the screws <NUM> to be fully screwed into the electrode main body <NUM> without hitting the floor (or a component of the apparatus <NUM>) beneath, the capacitor plate <NUM> with its electrode main body <NUM> is mounted at its four corners on four aluminum blocks <NUM> that raise it a certain distance from the floor and make room for the screws <NUM> to protrude from the bottom side of the electrode main body <NUM> when fully screwed in, i.e., when adjusted to their lowermost position. The highest position achievable is when the screws <NUM> are almost completely screwed out of the electrode main body <NUM>, but not quite. Generally, a little bit of play will be maintained to avoid unintended detachment of one of the screws <NUM> from the electrode main body <NUM> and/or a general loss of stability when coming close to the maximal height of the respective screw <NUM> above the electrode main body <NUM>.

A cover sheet <NUM> of electrically non-conductive material is arranged on the electrode main body <NUM> (s. <FIG>; in <FIG> the cover sheet is removed to reveal the arrangement of the screws <NUM>) and comprises openings in which the screws <NUM> are arranged. This not only helps to stabilize the screws <NUM> once they are in a medium or, in particular, a high position, i.e. screwed out to a large degree from the electrode main body <NUM>. It also provides for a stable and even support surface for the adjacent components of the apparatus <NUM>, in particular the molding tool <NUM>, to rest on (s. <FIG>, <FIG>, <FIG> and <FIG>).

Such a cover sheet <NUM> can generally be made from or comprise an electrically insulating cover. Preferably, the cover sheet <NUM> is made from or comprises one or more of the following materials: polytetrafluoroethylene (PTFE), polyethylene (PE), especially ultra-high molecular weight polyethylene (UHMWPE), polyether ketone (PEEK), a thermoplast, a duroplast, polyethylene terephthalate (PET), polyoxymethylene (POM), polystyrene (PS), an insulating mineral material. In the case shown in <FIG>, it is made from PTFE.

One option is that each of the adjustable segments/screws <NUM> can be set to one of at least the following four positions: removed (e.g., screwed out of the electrode main body <NUM>) or electrically disconnected, a low position, a medium position, a high position. On the other hand, e.g., for adjustable segments that are provided as screws <NUM>, it may also be possible to continuously vary their position in the z-direction, by turning or screwing them in or out to the desired degree (within the margins set by the lowermost and uppermost position, of course). Having a finite number of predetermined positions to which the segments/screws <NUM> are set can facilitate operation of the apparatus <NUM>. In <FIG>, <FIG>, <FIG> and <FIG>, exemplary screws being set to a low position, medium position and high position are indicated by reference numerals <NUM> (for low), <NUM> (for mid) and <NUM> (for high), respectively. In <FIG>, as indicated by the dashed-line ellipse 86x, one of the screws has been removed completely (alternatively, it could be electrically isolated from the capacitor plate <NUM>/ground potential).

It may be possible that the position of the segments/screws <NUM> can be adjusted while the molding cavity <NUM> is irradiated or flooded with electromagnetic radiation. Generally, however, for this to be possible an automated activation/adjustment mechanism will have to be employed (s. above), because during operation of the apparatus <NUM> a manual adjustment will generally not be allowed or possible, to avoid injuries.

As already discussed and explained above, adjusting the position of one or more of the segments/screws <NUM> influences the field strength distribution of the radiated electromagnetic field within the molding cavity <NUM>. For example, in <FIG> four regions or positions p1, p2, p3 and p4 are schematically indicated within the molding cavity <NUM>. These regions have screws <NUM> set to different positions/heights beneath them. For example, position p1 has screws set between the mid and low positions directly beneath it, position p2 has no screw at all beneath it (because the screw at position 86x has been removed), position p3 has again screws set between the mid and low positions directly beneath it, and position p4 has screws set between the mid and high positions directly beneath it. In this manner the electric field strength distribution, and hence the temperature and welding conditions, can be adjusted and controlled at the different positions p1 to p4.

The experimental results shown in <FIG> and <FIG> provide further insight into this aspect. On the left hand side of the two figures, different configurations of the apparatus <NUM> are schematically indicated that were used to investigate the heating rates and temperatures within a molding tool <NUM> under different positions of the screws <NUM> in the capacitor plate <NUM>. In each of the three cases investigated, two reference positions were considered within the molding tool, designated as P1 and P2, P3 and P4 as well as P5 and P6 in <FIG>-f, one in the front part of the tool (s. P1, P3 and P5, respectively), and one in the rear part of the tool (s. P2, P4 and P6, respectively). Using a constant setting of the radiation generator (not shown), and the different setting of the screws <NUM> as indicated in the left hand side of <FIG>-f, the heating rates/temperatures at the positions P1 - P6 were recorded over time, yielding the measurement curves C1 - C6 shown on the right hand side of <FIG>-f.

The x-axis in the measurement graphs on the right hand side of <FIG>-f shows time (the distance between two adjacent ticks or grid-lines on the x-axis corresponds to approximately <NUM> seconds in <FIG> and <FIG>), and the y-axis shows temperature (in the range form <NUM>° C to <NUM>° C in <FIG> and in the range form <NUM>° C to <NUM>° C in <FIG>).

In the upper case shown in <FIG> with all screws set to a medium/mid position <NUM>, the measurements at positions P1 and P2 yielded the measurement curves C1 and C2, respectively.

In the lower case shown in <FIG> with all screws set to a low position <NUM>, the measurements at positions P3 and P4 yielded the measurement curves C3 and C4, respectively.

In the case shown in <FIG> the screws in the front half of the tool were set to the medium position <NUM> and the screws in the rear half of the tool were set to the low position <NUM>, and the measurements at positions P5 and P6 yielded the measurement curves C5 and C6, respectively.

As can be deduced from the results, setting the position of the screw or screws <NUM> that correspond to a given measurement position to the medium position <NUM> leads to a greater heating rate (i.e., a greater increase in temperature per unit time = slope of the corresponding measurement curve) and a greater maximal temperature compared to setting the screw or screws <NUM> to the low position <NUM>. Further setting one or more of the screws <NUM> to a high position, or removing a screw or screws <NUM> completely, will further alter the heating rate/maximal temperature in accordance with this principle (e.g., the higher the screw position in z-direction, the greater the heating rate and maximal temperature, given a constant setting of the energy source).

The maximal temperature achieved in the experiment shown and discussed in relation to <FIG>, namely approximately <NUM>° C at positions P1 and P2 (s. curves C1 and C2) and approximately <NUM>° C at positions P3 and P4 (s. curves C3 and C4), as well as the maximal temperature achieved in the experiment shown and discussed in relation to <FIG>, namely approximately <NUM>° C at position P5 (s. curve C5) and approximately <NUM>° C at position P6 (s. curve C6), were all tailored to the specific material used to perform these experiments, namely particles <NUM> of expanded thermoplastic polyurethane (eTPU). In other words, the achieved temperatures were set to fall within the processing window of this specific material.

When particles <NUM> made of, or comprising, a different kind of material are used, the maximal temperature values will generally need to be adjusted to the specific processing characteristics and the available processing window for the material being used. Generally, the maximal temperature for processing any of the materials mentioned herein will not exceed <NUM>° C. For example, by increasing the applied voltage, the achieved maximal temperature values will generally also be increased. Changing the frequency of the applied electromagnetic field, e.g. from <NUM> to <NUM>, will also lead to a change in the achieved maximal temperature (and generally also to the heating rate, for example). As mentioned and discussed above, adjusting the segments/screws <NUM> to a higher position (i.e., a smaller value of d) will also lead to an increase in the (maximal) temperature at the corresponding position/region within the molding cavity <NUM>, so these factors are interrelated and have to be balanced against each other, as the skilled person understands.

Also, a material having a higher dielectric loss factor will generally heat up quicker and more strongly, so this also needs to be taken into account when exchanging the material and adjusting, e.g., the voltage, frequency and/or position of the segments/screws <NUM> as well as the duration of the manufacturing process.

Additionally to the above-described possibilities of adjusting the field distribution within the molding cavity <NUM>, the shape of the other capacitor plate, i.e., here the capacitor plate <NUM> that is connected to the radiation source, can also at least partially be adapted to the geometry of the part that is to be manufactured (i.e., the shoe sole or part of a shoe sole, like a midsole or part thereof). This "conventional and static" approach to adjusting the field distribution can hence supplement the "dynamical" adjustment possibilities provided by the segments <NUM> with adjustable distance d to the molding cavity <NUM> disclosed herein.

A fifth aspect of the present invention that goes hand in hand with the fourth aspect and that may also make use of, or rely on any of the options, embodiments and examples disclosed in the context of the first, second and/or third aspect of the present invention, is a method for the manufacture of a shoe sole or part of a shoe sole from foam particles <NUM>.

In an embodiment, the method comprises: a. ) loading the particles <NUM> into a molding cavity <NUM> of a molding tool <NUM> which is formed from at least two molding halves <NUM>, <NUM> which define the molding cavity <NUM>, wherein at least two capacitor plates <NUM>, <NUM> are arranged adjacent to the molding cavity <NUM>, wherein at least one of the capacitor plates <NUM> is connected to a radiation source, and wherein at least one of the capacitor plates <NUM> comprises several segments <NUM> that have an adaptable distance d to the molding cavity <NUM>; b. ) irradiating the molding cavity <NUM> with electromagnetic radiation emitted by the capacitor plates <NUM> and <NUM>; and c. ) locally adjusting a field strength distribution of the irradiating electromagnetic field within the molding cavity <NUM> by modifying the adaptable distance d of the segments <NUM> to the molding cavity <NUM>.

The modifying can occur before and/or during irradiation of the molding cavity <NUM> with the electromagnetic radiation.

The foam particles <NUM> can comprise, or be comprised of, one or more of the following base materials: thermoplastic polyurethane (TPU), polylactate(PLA), polyamide (PA), polyether block amide (PEBA), polyethylene terephthalate (PET), polybutylene terephthalate (PBT), and/or thermoplastic polyester ether elastomer (TPEE). As mentioned earlier, these foam particles are particles that comprise a so-called bead foam, also known in the art as a pellet / particle foam. Often the foams derived from the use of connected foam particles are given the designation "e" to denote the bead form of the polymer foam component, for example, eTPU.

Claim 1:
An apparatus (<NUM>) for the manufacture of a shoe sole or part of a shoe sole from foam particles (<NUM>), wherein the apparatus comprises:
a. a molding tool (<NUM>) which is formed from at least two molding halves (<NUM>, <NUM>) and which defines a molding cavity (<NUM>);
characterized in that it further comprises:
b. at least two capacitor plates (<NUM>, <NUM>) which are arranged adjacent to the molding cavity (<NUM>); wherein
c. at least one of the capacitor plates (<NUM>, <NUM>) is connected to a radiation source; and wherein
d. at least one of the capacitor plates (<NUM>, <NUM>) comprises several segments (<NUM>) that have an adaptable distance (d) to the molding cavity (<NUM>).