ES2896848A1 - Traceability capsule with controlled disintegration (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Traceability capsule with controlled disintegration. The present invention relates to a variety of traceability capsules. Within the capsules, a traceability device for the management and control of living beings can be included. The capsules have a controlled disintegration in time so that once its function is finished, they completely disintegrate without contaminating the environment. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Traceability capsule with controlled disintegration

The present invention relates to a variety of traceability capsules. Within the capsules, a traceability device can be included for the management and control of living beings. The capsules have a controlled disintegration in time so that once their function is finished they disintegrate completely without polluting the environment.

Background of the invention

The use of non-biodegradable labels or markers presents important ecological problems when discarded. Labels or markers are commonly made with laminated polyethylene ("PET") or a polyvinyl chloride ("PVC"), polypropylene, rubber vulcanized rubbers, nylon, acrylonitrile-butadiene-styrene thermopolymer ("ABS") , or polycarbonate ("PC").

Thus, in the state of the art we find the document with publication number CA1325720C which refers to an ear tag for animals to be used particularly for livestock, made with conventional plastics such as high and low density polyethylene, polypropylene, polyurethane, rubber, PVC, ABS or nylon. All these materials are non-degradable conventional plastics and represent a high rate of contamination.

The document with publication number EP2191715B1 refers to the recycling of animal identification tags that comprise electronic identification means for reuse, made of polyurethane.

Patent application US20080222930A1 describes a plastic ear tag for animals that includes a tag body and a locking insert, in which once the locking insert is placed inside the projection of a receptacle of the tag body ear, the insert does not come off easily from it. Furthermore, the present invention relates to an animal ear tag and a locking insert wherein the locking insert prevents separation of the locking components of the animal ear tag once the ear tag is installed. in an animal, thus inhibiting ear tag loss.

Patent application US20060190008A1 describes a plastic labeling system made up of a disposable injector.

As can be seen from the state of the art, it is necessary to develop new traceability capsules based on a degradable raw material that are rigid in use, but degradable once they are used.

Description of the invention

A new traceability capsule has been developed with materials that confer the necessary elasticity and rigidity to the capsule even in conditions of humidity, weather or contact with bacteria and the sun, maintaining its deteriorated condition once it is discarded, especially under composting conditions.

The capsule can be used in any farm animal from chicken to pig with different life expectancies, then the capsule must maintain its functionality between three months and several decades, in different climatic conditions and in different living environments. That is why the use of conventional plastics has been the quick solution to this problem, although it generates a serious problem of contamination by waste. The present invention solves this problem.

An RFID traceability device that is activated by proximity can be incorporated into the capsule of the invention, where traceability and other parameters such as vaccines, identification, possible interactions with other animals or herds, etc. are controlled to control their state of health. greet, position and life cycle among many other parameters. Due to the fact that the capsules can contain this device inside, the walls of the pieces must protect the antenna device during its useful life, which can vary from three months to decades, maintaining rapid degradation in a composting situation once the process is over. useful life of the device. The capsule can have a pin or clamp type fixation. The pin attachment is a small spike that goes through the traceability capsule.

The present invention shows a variety of mixtures taking advantage of the different materials and their properties in order to configure the same product but with different useful life periods. On the other hand, the mixtures are compatible with industrial manufacturing processes, especially by injection. Looking for texture, fluidity and suitable temperature for its manufacture to be feasible. In most of the materials in their pure state, we have detected that some of the injection manufacturing requirements are not met, either because of their low melting temperature that makes transformation impossible, or because they result in pieces that are either very rigid or too rigid. flexible, giving a defective product for use, or pieces that would not comply with the regulations of time for composting, since their environment of use, as in the case of pigs, was too bacterial and humid, or with the use of the Pure PLA results in pieces that are too hard and crystalline for short useful life times and are difficult to compost. Different polymers, with the same or different origins, were mixed until the proposed objectives were achieved. A mixture of different families of polymers was achieved that obtained the optimal duration for use, whether it was three months or years. In this way, ideal performance is achieved for each use, living being or object, all having in common the final disintegration in postage of the used materials.

By dividing the materials into families, different disintegration times were achieved by composting without the biodegradation of the material, during its life cycle, being a problem for the device. Thus, the chickens would have a device with a shorter life cycle and the cows another one with a longer life, but in the end they would decompose in compost without contaminating.

Degradable polymers are going to be used in the capsule of the invention. Polymers capable of degrading are understood to be those that indistinctly exceed the parameters of any of these regulations. EN 13.432: 2000 "Requirements for containers and packaging that can be recovered through composting and biodegradation", EN 14.855 "Determination of the final aerobic biodegradability and disintegration of plastic materials under controlled composting conditions", ASTM D6400-99 "Standard specification for compostable plastics ", ASTM D5338-98 "Standard test method for the determination of the aerobic degradation of plastic materials under controlled composting conditions", the ISO 14.851 standard on "Determination of the final aerobic biodegradability of plastic materials in aqueous media" .

The polymers that the capsule of the invention may comprise are the following:

Group A polymers, plastics of petrochemical and/or synthetic origin. Specifically group A are aliphatic polyesters and aromatic aliphatic polyesters.

Group B polymers, partially biobased plastics, selected from starch and polylactic acid, biodegradable polymers of fossil origin and their mixtures.

Group C are biobased plastics. They are those that are made from biomass, generally plants, algae and microorganisms. Unlike biopolymers that are generated directly in nature, such as starch, proteins, lignin and chitosan, biobased plastics require chemical processing steps before use. It is important to point out that the biobased origin of a plastic does not imply that it is biodegradable. Although there are cases such as PLA or PHA in which both conditions are met in a single material, the biodegradability of a plastic depends on its chemical structure, and not on the process or raw material by which it was produced. On the other hand, it should be mentioned that being biodegradable does not imply being compostable, since some parameters of toxicity and disintegration time are needed that result in biomass at the end of the process. PLA, being biodegradable, is not compostable in nature, so it is a material that, being biodegradable, is only compostable in industrial plants. From this family, the polymers of group C are selected from: PHA (polyhydroxyalkanoate), PHV (polyhydroxyvalerate), PHB (polyhydroxybutyrate), PHH (polyhydroxyhexanoate), PLA (polylactic acid), PDLA (poly-D-lactic acid), PDLLA (poly-D , L-lactic), TPS (thermoplastic starch), starch acetate, regenerated cellulose, cellulose acetate or bacterial cellulose and PO3G (polypropanediol), biodegradable polyamides Pa (polyamides) such as Pa-11 (polyamide 11).

Group D are polysaccharides.

Therefore, the invention refers to a traceability capsule comprising:

A polymer in a percentage by weight with respect to the total weight comprised between 50% weight/total weight and 99% weight/total weight selected from:

polymer of group A selected from aliphatic polyesters and aromatic aliphatic polyesters,

or from group B selected from starch and polylactic acid and biodegradable polymers of fossil origin and their mixtures,

or from group C selected from: PHA (polyhydroxyalkanoate), PHV (polyhydroxyvalerate), PHB (polyhydroxybutyrate), PHH (polyhydroxyhexanoate), PLA (polylactic acid), PDLA (poly D-lactic acid), PDLLA (poly D, L-lactic acid), TPS (thermoplastic starch), starch acetate, regenerated cellulose, cellulose acetate or bacterial cellulose and PO3G (polypropanediol).

or from group D selected from a polysaccharide;

1% weight/total weight to 50% weight/total weight of a mixture of at least two polymers selected from polymers from group A, B, C and/or D.

Total weight refers to the weight of all the compounds comprising the capsule.

Description of a preferred embodiment

Preferably, the polymer of group A is selected from: PEA (polyethylene adipate), polyesteramide, PES (polyether sulfone), PBS (polybutylene succinate), PBST (polybutylene terephthalate-succinate), PBSA (polybutylene succinate- co-adipate), PCL (polycaprolactone), PBSAT (polybutylene terephthalate succinate coadipate), PTMAT (poly (tetramethylene adipate/terephthalate), PVOH (polyvinyl alcohol), or PVA (polyinyl acetate).

Preferably, the polymer of group B is selected from: starch and polylactic acid.

Preferably, the polymer of group D is a polysaccharide obtained from biomass such as starch, cellulose, rubber, chitosan, proteins such as gelatin, collagen, zeins, gluten, soy or corn, or lipids such as triglycerides.

Preferably, to give greater strength to the piece, a non-toxic inorganic filler can be added. More preferably the inorganic filler is selected from carbonate salts. More preferably, the non-toxic inorganic filler is between 1% weight/total weight and 49% weight/total weight.

To facilitate and control disintegration, an organic oxidizing additive can be added. More preferably, the oxidizing organic additive is comprised between 1% weight/total weight and 3% weight/total weight.

EXAMPLES

The following examples are only illustrative of this invention, and should not be interpreted in a limiting sense thereof.

In all the examples the methods to quantify the color transmission capacity in the prepared samples are the following.

Example 1

A polymer blend composed of 63% PCL (polycaprolactone), plus 20% TPS (thermoplastic starch), plus 8% PHA (polyhydroxyalkanoates), plus 8% starch, plus 1% organic oxidizing agent .

It gives us as a result pieces with characteristics of rigid rubber, hydrophilic, resistant to light, and easy to disintegrate.

Example 2

A polymer mixture composed of 55% PBS (polybutylene succinate), plus 18% TDLA, plus 15% cellulose acetate, plus 11% an inert salt such as calcium carbonate, plus 1% an organic oxidizing agent.

Flexible, hard, very waterproof and slow disintegration.

Example 3

A polymeric mixture composed of 67% of a thermoplastic of mixtures of starch with biodegradable copolymers of fossil origin, plus a 24% mixture of PLA (polylactic acid) and PHA (polyhydroxyalkanoate) at 50%, plus 8% starch, plus 1% of an organic oxidizing agent.

It results in pieces with rigid, hydrophilic and rapid disintegration characteristics.

Example 4

A polymer blend composed of 82% polyamide, plus a 15% PLA (polylactic acid) blend and 3% organic oxidizing agent.

It results in pieces with characteristics of semi-flexible, high mechanical strength, water-repellent, resistant to environmental biodegradation and good degradation in composting.

Claims (6)

1. Traceability capsule comprising: A polymer in a percentage by weight with respect to the total weight comprised between 50% weight/total weight and 99% weight/total weight selected from: polymer of group A selected from aliphatic polyesters and aromatic aliphatic polyesters, or from group B selected from starch and polylactic acid and biodegradable polymers of fossil origin and their mixtures, or from group C selected from: PHA (polyhydroxyalkanoate), PHV (polyhydroxyvalerate), PHB (polyhydroxybutyrate), PHH (polyhydroxyhexanoate), PLA (polylactic acid), PDLA (poly D-lactic acid), PDLLA (poly D, L-lactic acid), TPS (thermoplastic starch), starch acetate, regenerated cellulose, cellulose acetate or bacterial cellulose and PO3G (polypropanediol), biodegradable polyamides Pa ( polyamides), Pa-11 (polyamide 11) or from group D selected from a polysaccharide; 1% weight/total weight to 50% weight/total weight of a mixture of at least two polymers selected from polymers from group A, B, C and/or D. 2. Traceability capsule according to claim 1 comprising between 1% weight/total weight and 3% weight/total weight of an oxidizing organic additive. 3. Traceability capsule according to any of claims 1 to 2 comprising from 1% weight/total weight to 49% weight/total weight of a non-toxic inorganic filler. 4. Traceability capsule according to claim 3, characterized in that the non-toxic inorganic filler is a carbonate salt. 5. Traceability capsule according to any one of claims 1 to 4, characterized in that the polymer of group A is selected from: such as PEA (polyethylene adipate), polyesteramide, PES (polyether sulfone), PBS (polybutylene succinate), PBST (Polybutylene Terephthalate Succinate), PBSA (Poly Butylene Succinate Co-adipate), PCL (Polycaprolactone), PBSAT (Polybutylene Terephthalate Succinate Coadipate), PTMAT (Poly Tetramethylene Dipate/Terephthalate), PVOH (polyvinyl alcohol) or PVA (polyvinyl acetate). 6.

Group D are polysaccharides. obtained from biomass such as starch, cellulose, rubber, chitosan, proteins such as gelatin, collagen, zeins, gluten, soy or corn, or lipids such as triglycerides, .