Process for the pretreatment of fibrous material, pretreatment chamber and fiber molding plant

Abstract

The present disclosure relates to a process for the pretreatment of fibrous material in a production process for producing three-dimensional products, to a pretreatment chamber for the pretreatment of fibrous material, and to a fiber molding plant having at least one pretreatment chamber. By pretreating relatively dry fiber material, the shaping step in a manufacturing process can be significantly improved and the choice of product geometries can be increased.

Claims

1. A process for pretreatment of fibrous material having a water content of less than 30% by weight in a production process for producing three-dimensional products, wherein the fibrous material is subjected to product-specific pretreatment before at least one process step of shaping three-dimensional products, wherein the at least one process step takes place directly after the pretreatment of the fibrous material, and wherein the fibrous material is at least partially moistened during the product-specific pretreatment.

2. The process according to claim 1, wherein during the product-specific pretreatment, the fibrous material undergoes at least one temperature, moisture, and/or steam treatment and/or the fibrous material undergoes an additive treatment.

3. The process according to claim 1, wherein the pretreatment comprises at least one pretreatment step.

4. The process according to claim 1, wherein selective pretreatment of the fibrous material is carried out.

5. The process according to claim 1, wherein the fibrous material is supplied for pretreatment in the form of separate preforms, as a sheet or as a continuous web.

6. The process according to claim 1, wherein, during selective pretreatment, only regions that are deformed in a subsequent process step are pretreated.

7. The process according to claim 1, wherein the pretreatment is carried out on a surface of the fibrous material at least from one side.

8. The process according to claim 1, wherein the pretreatment is carried out in a plurality of pretreatment steps.

9. The process according to claim 1, wherein the pretreatment takes place within a pretreatment chamber in which the fibrous material is at least temporarily protected from external influences.

10. The process according to claim 9, wherein at least one portion of the pretreatment chamber has properties that are different from a region around the pretreatment chamber, and wherein the properties include pressure, temperature, and/or moisture.

11. A pretreatment chamber for pretreatment of fibrous material that has a water content of less than 30% by weight, wherein the pretreatment chamber is part of a fiber molding plant for producing three-dimensional products, wherein product-specific pretreatment of the fibrous material can be carried out in the pretreatment chamber, and said pretreatment chamber has at least one pretreatment device with which the fibrous material introduced therein undergoes at least one temperature, moisture, and/or steam treatment and/or undergoes an additive treatment.

12. A fiber molding plant comprising at least one pretreatment chamber according to claim 11, wherein the at least one pretreatment chamber is arranged upstream of at least one molding station.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] In the drawings:

[0034] FIG. 1 depicts a schematic view of a fiber molding plant for producing three-dimensional products from a fibrous material, according to some embodiments.

[0035] FIG. 2 depicts a further schematic view of a fiber molding plant for producing three-dimensional products from a fibrous material, according to some embodiments.

[0036] FIG. 3 depicts a schematic view of a further fiber molding plant for producing three-dimensional products from a fibrous material, according to some embodiments.

DETAILED DESCRIPTION

[0037] Embodiments of the technical teaching described herein are shown below with reference to the drawings. Identical reference signs are used in the figure description for identical components, parts and processes. Components, parts and processes that are not essential to the technical teachings disclosed herein or that are obvious to a person skilled in the art are not explicitly reproduced. Features specified in the singular also include the plural unless explicitly stated otherwise. This applies in particular to statements such as a or one.

[0038] The drawings show embodiments of a fiber molding plant 100 having at least one pretreatment chamber 120; 140 and at least one molding station 130; 150. The exemplary embodiments shown here do not represent any restriction with regard to further embodiments and modifications of the described embodiments. Thus, alternative embodiments for individual exemplary embodiments can also be provided alternatively or cumulatively in other exemplary embodiments.

[0039] FIG. 1 is a schematic view of a fiber molding plant for producing three-dimensional products from a fibrous material. The fiber molding plant 100 makes it possible to produce products that are biodegradable and can themselves again serve as a starting material for the production of three-dimensional products from a fibrous material, and can be composted because they can generally be fully decomposed and do not contain any worrying, environmentally hazardous substances. The products can, for example, be designed as cups, lids, bowls, capsules, plates and further molded and/or packaging parts (e.g., as holding/support structures for electronic devices or other devices).

[0040] In the embodiment shown, a material web 200 made of a fibrous material is processed. The material web 200 contains fibers of natural origin and has a moisture content of less than 30% by weight of water.

[0041] In the illustrated embodiment, the fiber molding plant 100 has a feeder 110. The feeder 110 can, as schematically indicated, also have a transport device that serves to transport a material web 200, web sections or premolded preforms. The transport device can have different designs. Depending on the design of a pretreatment chamber 120; 140, a transport device can also support or hold a material web 200 or other fibrous material, only in certain regions, in order to also enable treatment from the bottom side. In the design shown, a material web 200 is unwound from a roll and fed continuously in the processing direction to a first pretreatment chamber 120. The material web 200 passes through the first pretreatment chamber 120 and is subjected to three pretreatment steps (I., II., III.). During pretreatment, properties of the material web 200 are selectively influenced in a product-specific manner in order to immediately subsequent shaping is supported or only possible. For this purpose, the material web 200 is fed to a first molding station 130 after pretreatment. In the molding station 130, regions of the material web 200 are deformed and receive their final three-dimensional shape.

[0042] The feed of the material web 200 can be carried out continuously or cyclically via the feeder 110. In the embodiment shown, pretreatment and shaping take place during a feed pause. To ensure continuous unwinding of the material web 200, length compensation devices can be provided, as are known, for example, in thermoforming systems for plastics films.

[0043] The fiber molding plant 100 may have additional stations and devices. For example, a reserve may be provided for fibrous material. In further designs, a grinder can be provided for comminuting a starting material and for separating fibers, which can then be pretreated as an airlaid material.

[0044] The pretreatment chamber 120 may include a housing that surrounds the space where pretreatment takes place. The pretreatment chamber 120 has a passage on the inlet and outlet sides, which can be closed in other designs. Thus, the space within the pretreatment chamber 120 can be substantially sealed and/or decoupled from its surroundings so that other conditions (temperature, moisture, pressure) can prevail within the pretreatment chamber 120, at least temporarily.

[0045] In the embodiment shown in FIG. 1, the pretreatment chamber 120 has a first portion I., a second portion II. and a third portion III., which in further embodiments can be separated from one another and sealed off, or at least are separable and sealable.

[0046] The pretreatment chamber 120 has at least one first spraying device 122 and at least one first heating device 123 in the first portion I. The second portion II. includes second spraying devices 124. The third portion III. has at least one second heating device 126 and third spraying devices 127.

[0047] The at least one first molding station 130 has an upper first tool part 131 and a lower second tool part 133. The first tool part 131 has a plurality of cavities 132, and the second tool part 133 has a plurality of corresponding mold parts 134. In order to mold products, the two tool parts 131 and 133 are moved relative to each other, where the pretreated regions of the material web 200 are pressed between the surfaces of the cavities 132 and the molded parts 134 by applying pressure and heat. For example, pressing can be carried out under specific pressures in the range of 100 N/cm.sup.2 to 5,000 N/cm.sup.2 and temperatures of 20 (cold pressing) to 250 C. (hot pressing).

[0048] After the deformation/pressing in the molding station 130, the pressed products are fed in the transport direction to a further station and/or removed from the fiber molding plant 100. Optional post-processing of the manufactured products may include printing, dyeing, filling, stacking, etc. This can be done, for example, in at least one processing station 160, as shown schematically in FIG. 3.

[0049] In the first portion I., during a first pretreatment step, first regions 210 are first sprayed by the first spraying devices 122 with an additive that changes or influences the properties of the fibrous material in the sprayed region. For example, additives can be applied to the surfaces of the material web 200 from both below and from above. As shown schematically in plan view in FIG. 2, spraying is carried out in circles in the region of the dashed line. The regions 210 provided with the additives are then dried in the first portion I. using the first heating devices 123. In order to achieve this, cyclical feed is carried out, where in the embodiment shown the material web 200 is substantially always moved to the right by just one (shown vertically in FIG. 2) row of regions 210.

[0050] The material web 200 is then moved further. The regions 210 previously provided with additives and dried are then subjected to further pretreatment in the second portion II. by means of the second spraying devices 124. The second spraying devices 124 can, for example, moisten a portion 220 of the material web 200 and thus increase the moisture content. For example, additional additives can be applied. In further embodiments, the entire fibrous material of the portion 220 of the material web 200 is permeated by steam in the second portion II.

[0051] The material web 200 is then moved to a third portion III, in which the material web 200 is initially dried by the second heating devices. Subsequently, regions 230 are also moistened by the third spraying devices 127.

[0052] As shown in FIG. 2, the regions 210, 230 differ so that different material properties of the fibrous material of the material web can be achieved by the fact they have a different moisture content. In the embodiment shown, inclined surfaces are subject to greater deformation during pressing in the molding station 130 so that the fibrous material in these regions must have different properties with regard to deformability than, for example, in a base region of a bowl, cup or lid to be produced. This is achieved by product-specific selective moistening of regions of the fibrous material, which can be subjected to stronger/greater deformation in moist regions than in other regions.

[0053] For example, regions of the fibrous material can be moistened with from 20 to 50 wt. % water. In order to prevent damage to the material during subsequent pressing at high temperatures, the total moisture content of the material in a mold space between the surfaces of a cavity 132 and a corresponding molded part 134 can be adjusted so that it does not exceed, for example, 20% by weight. The adjustment is made according to the moisture content of the corresponding regions.

[0054] For controlling the production steps and the pretreatment, the fiber molding plant 100 also has at least one controller, which in further embodiments is connected to at least one monitoring device (e.g. camera, sensors, etc.) in order to adapt and regulate the moisture content of regions of the fibrous material and the pretreatment.

[0055] FIG. 3 is a schematic view of a further fiber molding plant 100 for producing three-dimensional products from a fibrous material, which additionally has at least one second pretreatment chamber 140 and a second molding station 150. The second pretreatment chamber 140 has a fourth portion IV. and a V. portion in which further additives and/or product-specific moistening of surfaces of the material web 200 to be deformed takes place.

[0056] For example, in the first pretreatment chamber 120, in addition to the application or introduction of additives, moistening can take place for preforming the fibrous material. In this case, the fibrous material is preformed immediately after the first pretreatment so that it substantially already assumes the shape of the product to be manufactured. Subsequently, further additives (e.g. for a barrier) can be applied in the second pretreatment chamber 140; in addition, regions to be molded can be (re) moistened. The final molding and/or pressing step can then take place in the second molding station 150.

[0057] In further embodiments, for example, in a second molding step in a second molding station 150, grooves can be formed in an already shaped inclined side wall. Other embossed elements can also be introduced in different designs.

[0058] In addition, the surface finish and properties of the product to be manufactured can be significantly influenced and improved in a two-step molding or pressing process. For example, after a first molding step, the entire product, for example, can be moistened again and/or post-pressed with a different pressure and/or temperature.

[0059] Direct (inline) product-specific pretreatment of fibrous material is described, which enables an automatic dry fiber manufacturing process in a fiber molding plant 100, where there are no restrictions with regard to the product geometry due to the dry fiber material used.

[0060] One or more states of the fibrous material can be changed in a pretreatment chamber 120; 140 in one or more segments (I., II., III./IV., V.). The fibrous material can be fed from a roll or in cut pieces and transported through the pretreatment chamber 120; 140. Pretreatment can be carried out on one or both sides, once or in combined applications, continuously or in process steps. In addition, selective pretreatment is carried out, where product geometry-specific regions are given a high amount of moisture (20-50%), for example, but the total moisture content can be limited from a damage/weakening of the material perspective.

[0061] In addition to increasing elongation and flow behavior, the strength of the molded products is also increased and the surface becomes smoother and more stable (no linting). Advantageously, pretreatment takes place before a process step, in particular a molding step. It is also possible to divide the pretreatment, for example by having a pretreatment step between two process steps, in order to apply moisture locally again after preforming with a hot mold, in order to produce the final product geometry.

[0062] Energy is also saved because less moisture is introduced into the material, so less energy is also required to remove the moisture during pressing. In other embodiments, in accordance with the (total) moisture content, cold pressing (e.g. at room temperature, approx. 20 C.) can also be carried out, since the moisture can be distributed throughout the product under high pressure and thus does not lead to locally wet regions.

List of Reference Signs

[0063] 100 Fiber molding plant [0064] 110 Feeder [0065] 120 First pretreatment chamber [0066] 122 First spraying device [0067] 123 First heating device [0068] 124 Second spraying device [0069] 126 Second heating device [0070] 127 Third spraying device [0071] 130 First molding station [0072] 131 First tool part [0073] 132 Cavity [0074] 133 Second tool part [0075] 134 Molded part [0076] 140 Second pretreatment chamber [0077] 150 Second molding station [0078] 160 Processing station [0079] 200 Material web [0080] 210 First regions [0081] 220 Portion [0082] 230 Second regions