DE102022132743A1 - Thermoplastic material - Google Patents

Abstract

The invention relates to a thermoplastic material, wherein the material contains starch and further components, wherein the further components comprise cellulose and talc as fillers, wherein the further components comprise sorbitol as plasticizer in a concentration of at least 5 wt.% and at most 9.5 wt.% sorbitol based on the total weight of the material in the dried state.

Description

The invention relates to a thermoplastic material and a method for producing a molded body from a thermoplastic material and to a molded body.

From the state of the art, for example the EP 0 397 819 A1 , thermoplastic materials are known that contain starch and other components. Such thermoplastic materials can be used as biodegradable materials that can be produced from renewable resources. Due to the increased environmental awareness of consumers in the past, such materials are enjoying increasing popularity.

The disadvantage of such materials, however, is that they do not have sufficient resistance for many uses, for example to moisture. This makes materials of the type in question currently unsuitable for many applications. For example, utensils that are typically used in bathrooms cannot usually be made from materials of the type in question due to the high humidity that prevails there, as they would absorb moisture and thus soften so quickly that they would hardly be suitable for the manufacture of products with a reasonable service life under such conditions.

From the US 2012/0022188 A1 Materials containing starch are also known. However, these materials contain significant amounts of petroleum-based plastics. These in turn have a negative effect on biodegradability.

Overall, there is therefore a conflict of objectives between the properties of the known materials. The properties that are important for materials of the type in question include in particular their resistance to moisture, but also their other, particularly mechanical, properties, their processability, which includes in particular flowability during injection molding, but also their biodegradability.

The invention is therefore based on the object of demonstrating a thermoplastic material and a method for producing a molded body from a thermoplastic material, as well as a molded body which has an overall advantageous combination of the above-mentioned properties and which has at least satisfactory properties with regard to durability, mechanical properties, processability and degradability.

The object is achieved by a material and a method as well as a molded body having the features of the independent claims. The features of the dependent claims relate to advantageous embodiments.

The problem is solved by a thermoplastic material that contains starch and other components. The other components include cellulose and talc as fillers. The other components also include sorbitol as a plasticizer in a concentration of at least 5% by weight and at most 9.5% by weight of sorbitol based on the total weight of the material in the dried state. It has been shown that particularly good mechanical properties can be achieved by combining these fillers with sorbitol as a plasticizer in the specified concentration range. In particular, a good compromise between tensile strength and ductility can be achieved.

In practice, drying the components to a residual moisture content of 0% by weight is often difficult, so the concentrations in the dried state with regard to the material and/or its components are to be understood in particular as the theoretical water-free concentrations after calculating out any residual moisture still present in the material and/or its components. The residual moisture can be determined by means of a suitable measurement.

The concentration of the starch can be in particular at least 45% by weight, in particular at least 47.5% by weight and/or at most 55% by weight, in particular at most 52% by weight of starch based on the total weight of the material in the dried state. The starch can in particular be corn starch.

The other components may also include other fillers. The other fillers may in particular be chalk, bentonite, mustard seed shells, organic fibres and/or waste It has proven advantageous if the total concentration of fillers is at least 22.5% by weight, in particular at least 26% by weight and/or at most 37% by weight, in particular at most 33% by weight, based on the total weight of the material in the dried state.

In particular, the other components can comprise talc as a filler in a concentration of at least 21% by weight, in particular at least 23.6% by weight, and/or at most 29% by weight, in particular at most 27% by weight, of talc based on the total weight of the material in the dried state. It has been shown that with this concentration of talc as a filler, very good mechanical properties can be achieved, while the material still remains sufficiently processable.

In particular, the other components can comprise cellulose as a filler in a concentration of at least 1.5% by weight, in particular 2.4% by weight, and/or at most 8% by weight, in particular at most 6% by weight, of cellulose based on the total weight of the material in the dried state. It has been shown that with this concentration of cellulose, particularly good surface qualities of the material can be achieved.

In particular, the other components can comprise plasticizers in a total concentration of at least 16.5% by weight, in particular at least 19% by weight and/or at most 25.3% by weight, in particular at most 23.3% by weight of plasticizer, based on the total weight of the material in the dried state. It has been shown that this content of plasticizer leads to a particularly good compromise between hardness, strength, ductility and flow behavior during processing in a material of the type in question.

In particular, the further constituents may comprise glycerin as a plasticizer in a concentration of at least 11.5% by weight, in particular at least 12.5% by weight and/or at most 15.8% by weight, in particular at most 14.8% by weight of glycerin based on the total weight of the material in the dried state.

In particular, the further constituents may comprise sorbitol as a plasticizer in a concentration of at least 5% by weight, in particular at least 6.5% by weight and/or at most 9.5% by weight, in particular at most 8.5% by weight of sorbitol based on the total weight of the material in the dried state.

It has been shown that when glycerin and sorbitol are used as plasticizers in exactly these concentrations, a significantly increased resistance of the thermoplastic material or of objects made from the thermoplastic material to moisture can be observed. Surprisingly, the ratio of the amounts of sorbitol and glycerin to one another also plays a role.

In addition to the components mentioned above, the material may also comprise other components. These other components are in particular components that are biodegradable and/or consist of renewable raw materials and/or are bio-inert inorganic components.

In particular, the material is free of petroleum-based components, and in particular free of petroleum-based plastics as a component. Petroleum-based components, in particular petroleum-based plastics, have a negative effect on the biodegradability of the material or molded articles made from it. Alternatively and/or additionally, the proportion of biogenic carbon in the total carbon of the material can be at least 99%. In this context, the proportion of biogenic carbon in the total carbon of the material is to be understood in particular as the proportion of biogenic carbon in the total carbon of the material determined according to ASTM D 6866.

In particular, the components are selected such that the thermoplastic material is industrially compostable and/or home compostable. In this context, a home compostable material is understood to mean in particular a material that is considered home compostable according to the standard NF T51-800:2015-11-14. In this context, an industrially compostable material is understood to mean in particular a material that is considered home compostable according to the standard EN 13432:2000-12 is considered industrially compostable.

The method for producing the material can provide that the components of the thermoplastic material described above are filled into an extruder and extruded. The extruder in particular causes the material to be pressed through the nozzles. The extruder can in particular be a twin-screw extruder. When carrying out the method, the extruder not only extrudes but also melts and/or homogenizes the material.

In particular, the components are mixed before extrusion, i.e. in particular before the mixed components of the material are introduced into the extruder, in particular the twin-screw extruder.

Preferably, the mixing and/or the extrusion is carried out in such a way that the residual moisture of the material and/or of its components immediately before and/or immediately at the start of the extrusion is less than 3% by weight. Particularly preferably, the mixing and/or the extrusion is carried out in such a way that the residual moisture of the material and/or of its components immediately before and/or immediately at the start of the extrusion is less than 2% by weight. In particular, the material and/or its components can be dried during the mixing. It has been shown that, in conjunction with the compositions described above, the production of a starch-based thermoplastic material can also be successful with such low residual moisture of the components or of the resulting thermoplastic material.

The thermoplastic material described above can be used as a starting material in a process for producing a molded body. For this purpose, the material can be in the form of granules, for example. For this purpose, it can be formed into strands through nozzles and then cut, in particular into sections a few millimeters long. The extruder in particular presses the material through the nozzles.

The method for producing a molded body provides that a thermoplastic material described above and/or a thermoplastic material produced as described above is processed into a molded body. It has been shown that such a thermoplastic material can be used to produce molded bodies.

The process for producing a molded body from the thermoplastic material can in particular be an injection molding process. Injection molding processes are particularly suitable for the cost-effective production of molded bodies in large quantities. It has been shown that the material described above or produced as described above is well suited to processing by means of injection molding.

The fact that the thermoplastic material has good flowability even with low residual moisture has a particularly positive effect. In practice, starch-based thermoplastic materials are often mixed with water and processed in specialised injection moulding machines in which the material is dried. This leads to longer cycle times and thus high unit costs. The material described can be processed in an injection moulding machine in particular with a residual moisture content of less than 1% by weight. The material can be heated to a temperature of at least 180°C, in particular at least 190°C, and/or at most 210°C, in particular at most 230°C, to liquefy it. This enables the use of standard plastic injection moulding machines for thermoplastics and also short cycle times.

In particular, the injection molding process can be carried out in a hot runner injection molding system. The hot runner injection molding systems can in particular have needle valves for the injection molding nozzles. Such injection molding systems offer the advantage that the material is kept liquid up to the nozzle outlet. This avoids the formation of a sprue. On the one hand, this avoids the formation of waste material or the need for corresponding post-processing, and on the other hand, the quality of the molded bodies that can be produced is increased by the absence of a sprue.

• 1 bis 4: Messungen mechanischer Eigenschaften beispielhafter Materialzusammensetzungen mit einer variierten Konzentration von Talkum als Füllstoff
• 5 bis 8: Messungen mechanischer Eigenschaften beispielhafter Materialzusammensetzungen mit einer variierten Konzentration von Cellulose als Füllstoff.
• 9 bis 18 Messungen mechanischer Eigenschaften einer besonders vorteilhaften Materialzusammensetzung im Vergleich zu Vergleichszusammensetzungen mit unterschiedlichen Anteilen der Weichmacher Sorbitol und Glycerin.

Further practical embodiments and advantages of the invention are described below in conjunction with the drawings.

• 1 to 4 : Measurements of mechanical properties of exemplary material compositions with a varied concentration of talc as filler
• 5 to 8 : Measurements of mechanical properties of exemplary material compositions with a varied concentration of cellulose as filler.
• 9 to 18 Measurements of mechanical properties of a particularly advantageous material composition in comparison to comparison compositions with different proportions of the plasticizers sorbitol and glycerin.

All concentration data given below refer to the material in the dried state.

In practice, it has been shown that the concentrations of the different components, in particular the total concentration of fillers and plasticizers, as well as the concentrations of sorbitol, glycerin, talc and cellulose, influence each other with regard to the properties of the resulting materials.

Therefore, only exemplary measurements for different properties of various material compositions are given below.

In the 1 to 4 The results of mechanical tests on thermoplastic materials containing different amounts of talc as a filler are shown. The concentrations of the components of the individual materials can be found in Table 1 below: Table 1 Corn starch (wt%) 75% 67.5% 60% 52.5% Sorbitol (wt%) 7.5% 6.75% 6% 5.25% Talc (wt%) 0% 10% 20% 30% Glycerin (wt%) 17.5% 15.75% 14% 12.25%

It is evident that with increasing concentration of talc in the concentration range under consideration, an improvement can be achieved, particularly in the tensile modulus and tensile strength. The impact strength and elongation (until the sample breaks) initially increase from low concentrations of talc, then decrease slightly and then remain constant.

However, it has also been shown that if the concentration of talc is too high, the abrasiveness of the material increases, which affects its processability. Therefore, increasing the proportion of talc beyond certain limits, which also depend on the other components of the material, does not seem to make sense.

In the 5 to 8 The results of mechanical tests on thermoplastic materials containing different amounts of cellulose as a filler are shown. The concentrations of the components of the individual materials can be found in Table 2 below: Table 2 Corn starch (wt.%) 67.5% 63.75% 60% 56.25% 52.5% Sorbitol (wt%) 6.75% 6.375% 6% 5.625% 5.25% Talc (wt%) 10% 10% 10% 10% 10% Glycerin (wt%) 15.75% 14.875% 14% 13.125% 12.25% Cellulose (wt%) 0% 5% 10% 15% 20%

It turns out that the dependence of the properties on the concentration is less clear for cellulose than for talc. In particular, a significant continuous reduction in elongation (until the sample breaks) is observed for high cellulose contents. However, even relatively low concentrations of cellulose can significantly increase the tensile strength.

Based on the measurements carried out, an exemplary thermoplastic material has proven to be particularly advantageous in terms of overall properties. Its composition is shown in Table 3 below: Table 3 % by weight Corn starch 49.3% Sorbitol 7.4% talc 25.3% Glycerine 13.7% Cellulose 4.2%

In the following 9 to 18 the results of the measurements of the properties of this material are marked with an X. In addition to the properties of this material, the 9 to 18 the properties of comparison materials are shown. The compositions of the comparison materials were deliberately varied with regard to the ratio between stronger plasticizers and the ratio between glycerin and sorbitol. The compositions of the comparison materials can be seen in Tables 4 to 6: Table 4 Starch : plasticizer 2 2 2 Glycerin : Sorbitol 1.5 2.5 3.5 Corn starch (wt%) 53.33% 53.33% 53.33% Sorbitol (wt%) 10.67% 7.62% 5.93% Talc (wt%) 20% 20% 20% Glycerin (wt%) 16% 19.05% 20.67% Table 5 Starch : plasticizer 3 3 3 Glycerin : Sorbitol 1.5 2.5 3.5 Corn starch (wt%) 60% 60% 60% Sorbitol (wt%) 8th% 5.71% 4.44% Talc (wt%) 20% 20% 20% Glycerin (wt%) 12% 14.29% 15.56% Table 6 Starch : plasticizer 4 4 4 Glycerin : Sorbitol 1.5 2.5 3.5 Corn starch (wt%) 64% 64% 64% Sorbitol (wt%) 6.4% 4.57% 3.56% Talc (wt%) 20% 20% 20% Glycerin (wt%) 9.6% 11.43% 12.44%

It can be seen that the strength values, i.e. hardness, tensile modulus, flexural modulus, flexural strength and tensile strength of the exemplary material in particular have good values compared to the comparison materials. As expected, the mechanical properties show a strong dependence on the total concentration of the plasticizers contained. The exemplary material represents an optimization within this fundamental context, which not only leads to a good profile of mechanical properties, but also enables the material to be processed well. In particular, the exemplary material can be processed in injection molding machines in a dry state, i.e. in particular with residual moisture of less than one percent. This means that unmodified plastic injection molding machines can be used, which would not make sense to use with starch-based thermoplastic materials that require a significant water content to achieve satisfactory flowability.

The features of the invention disclosed in the present description, in the drawings and in the claims can be essential for the realization of the invention in its various embodiments both individually and in any combination. The invention is not limited to the embodiments described. It can be varied within the scope of the claims and taking into account the knowledge of the competent person skilled in the art.

QUOTES INCLUDED IN THE DESCRIPTION

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

Cited patent literature

• EP 0397819 A1 [0002]
• US 20120022188 A1 [0004]

Cited non-patent literature

• EN 13432:2000-12 [0020]

Claims (14)

Thermoplastic material, wherein the material contains starch and further components, wherein the further components comprise cellulose and talc as fillers, wherein the further components comprise sorbitol as plasticizer in a concentration of at least 5 wt.% and at most 9.5 wt.% sorbitol based on the total weight of the material in the dried state. Material according to Claim 1 , characterized in that the concentration of the starch is at least 45 wt.%, in particular at least 47.5 wt.% and/or at most 55 wt.%, in particular at most 52 wt.% starch based on the total weight of the material in the dried state. Material according to one of the preceding claims, characterized in that the total concentration of the fillers is at least 22.5% by weight, in particular at least 26% by weight, and/or at most 37% by weight, in particular at most 33% by weight, based on the total weight of the material in the dried state. Material according to one of the preceding claims, characterized in that the further constituents comprise talc as filler in a concentration of at least 21% by weight, in particular at least 23.6% by weight, and/or at most 29% by weight, in particular at most 27% by weight, of talc based on the total weight of the material in the dried state. Material according to one of the preceding claims, characterized in that the further constituents comprise cellulose as filler in a concentration of at least 1.5% by weight, in particular 2.4% by weight, and/or at most 8% by weight, in particular at most 6% by weight, of cellulose based on the total weight of the material in the dried state. Material according to one of the preceding claims, characterized in that the further constituents comprise plasticizers in a total concentration of at least 16.5% by weight, in particular at least 19% by weight, and/or at most 25.3% by weight, in particular at most 23.3% by weight, of plasticizers based on the total weight of the material in the dried state. Material according to one of the preceding claims, characterized in that the further constituents comprise glycerin as a plasticizer in a concentration of at least 11.5% by weight, in particular at least 12.5% by weight, and/or at most 15.8% by weight, in particular at most 14.8% by weight, of glycerin based on the total weight of the material in the dried state. Material according to one of the preceding claims, characterized in that the further constituents comprise sorbitol as a plasticizer in a concentration of at least 5% by weight, in particular at least 6.5% by weight, and/or at most 9.5% by weight, in particular at most 8.5% by weight, of sorbitol based on the total weight of the material in the dried state. Material according to one of the preceding claims, characterized in that the material is free from petroleum-based components, in particular free from petroleum-based plastics as a component, and/or the proportion of biogenic carbon in the total carbon of the material is at least 99%. Material according to one of the preceding claims, characterized in that the components are selected such that the thermoplastic material is industrially compostable and/or home compostable. Process for producing a thermoplastic material according to one of the preceding claims, characterized in that the components of the thermoplastic material are mixed and extruded in order to obtain the thermoplastic material, wherein the mixing and/or the extrusion is carried out in such a way that the residual moisture of the material and/or of its components immediately before and/or immediately at the start of the extrusion is below 3% by weight, in particular below 2% by weight. Process for producing a molded body, characterized in that the molded body is made of a thermoplastic material according to one of the Claims 1 until 10 and/or from a proceeding pursuant to Claim 11 manufactured thermoplastic material. Procedure according to Claim 12 , characterized in that the thermoplastic material is processed into the molded body in an injection molding process, in particular in a hot runner system, wherein the thermoplastic material is heated to a temperature of at least 180°C, in particular at least 190°C, and/or at most 210°C, in particular at most 230°C, in order to liquefy it. Moulded body made from a material according to Claim 1 until 10 and/or from a proceeding pursuant to Claim 11 manufactured thermoplastic material and/or manufactured by a process according to Claim 12 or 13 .