• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Eco-sustainable method of recycling by encapsulation, diversification and reuse, of by-products or various residual products; which includes: a) a selection and preprocessing of by-products or residual products, by volumetric transformation, if necessary, by cutting or deformation; b) the preparation of an ecologically sustainable acrylic-cementitious polymeric bio-mortar, comprising: - a fragile binder, cement, lime, plaster or the like; - light loads that enclose a considerable amount of air inside its molecular interior; - acrylic polymeric additives, reinforcing fibers and water and, - optionally, acrylic dyes and oxidizers such as iron sulfates, copper sulfate, natural pigments, earth, walnut or the like; c) Obtaining a new bio-product made by coating or encapsulating, of various residual products, with a layer of bio-mortar that covers, waterproofs, insulates, protects and decorates totally or partially. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2731686A1
    申请号:ES201830472
    申请日:2018-05-17
    公开日:2019-11-18
    发明作者:Callis Abel Castane
    申请人:Callis Abel Castane;
    IPC主号:
    专利说明:

    [0001] Eco-sustainable recycling method by encapsulation, diversification and reuse, of various by-products or residual products.
    [0002]
    [0003] Description of the invention
    [0004]
    [0005] The present invention relates to an eco-sustainable method of recycling by encapsulation, diversification and reuse, of by-products or residual products, obsolete and of little or no commercial value, based on the reuse of the physical qualities that still maintain some or some of its components, structures and formats.
    [0006]
    [0007] This method comprises a preprocessing of the by-products or residual products, which comprises at least one of the following operations: selection, exploded volumetric transformation or deformation thereof by any means; and, subsequently, its coating, and micro-particular or corporeal encapsulation, with biomorteros and eco-sustainable mortars that also include loads of plastic, mineral, vegetable or organic origin mixed with polymeric additives and natural or synthetic acrylic copolymers, in addition to water and fragile binder products.
    [0008]
    [0009] Field of application of the invention.
    [0010]
    [0011] The invention is framed in the field of recycling obsolete, residual products and various by-products, as well as in the field of the most sustainable bio-construction.
    [0012]
    [0013] Background of the invention
    [0014]
    [0015] At present, a large number of by-products and industrial, domestic, forest, botanical, and other residual products. they are discarded or discarded as obsolete and unusable, either because their cost of reuse is not profitable or because they do not find formulas or ideas to be put back on the market through sustainable transformation processes both economically and for their great impact environmental, being in fact ruled out its possibility of new regeneration, reuse and even less of its qualitative improvement in terms of new benefits, utilities and new commercialization.
    [0016]
    [0017] At present, a wide variety of by-products and residual products from various sectors are going to systematically end up in more or less controlled landfills, are improperly incinerated, or are compacted and packed for disposal, all with an important economic and environmental cost. additionally and simply to remove them from the chain of consumption, but in no case do they take advantage of most or much of their “still permanent intrinsic and morphological physicochemical qualities” from both their cellular, molecular and structural composition, as well as the retention capacity and air content inside for its shape, thanks to its formulation, format or simply for its optimal, unique and exceptional weight / volume ratio.
    [0018]
    [0019] The applicant of the present invention is unaware of the existence of antecedents oriented to the industrial, specific and massive use of the qualities of these by-products or residual products.
    [0020]
    [0021] Therefore, the technical problem that arises is the development of an eco-sustainable method of recycling by encapsulation, diversification and reuse, of by-products or diverse and obsolete residual products.
    [0022]
    [0023] Description of the invention
    [0024]
    [0025] The method of the invention has characteristics aimed at reducing the negative environmental impact and sustainable use of residual products and by-products, basically light, which in their cellular and molecular physical-chemical structure incorporate or trap a large amount of air, such as: containers and plastic packaging; by-products of the wood and cork industry, mineral fibers such as rock wool, vegetable fibers such as coconut fiber, and other insulating products of plastic origin such as polystyrenes, polyurethanes, polyisocyanurates, phenolic foams etc., residual products of origin organic such as those from leather or skin. For this, the invention contemplates the reuse of said by-products or residual products for the sustainable manufacture of new objects and elements made in whose composition involves said by-products and residual products, in a high percentage, between 25% and 85% of the new bio-product.
    [0026]
    [0027] Due to the large contribution of air made by the aforementioned by-products, the new bio-product obtained is characterized by low density, high thermo-acoustic insulation, manageability, ease of attachment and transport, high deformability and special resistance to flexotraction .
    [0028]
    [0029] The selection of said by-products and residual products will be made in accordance with the bio-product to be obtained, being able to combine between one or several elements to be reused to those that are mixed, joined or coated with bio-mortars and acrylic bio-mortars of composition also , preferably based on residual and sustainable products, obtained especially and abundantly in manufacturing processes, handling, cutting, cutting and residual crushing, especially by different manufacturers and installers of thermal and plastic products.
    [0030]
    [0031] According to the invention, this eco-sustainable method of recycling by encapsulation, diversification and reuse, of various by-products or residual products, comprises:
    [0032]
    [0033] a) a preprocessing of the by-products or residual products, which includes at least one of the following operations: selection, volumetric transformation and cutting or deformation thereof by any means;
    [0034]
    [0035] b) the preparation of an ecologically sustainable polymeric acrylic-cementitious bio-mortar encapsulation, comprising:
    [0036] - a fragile binder product, cement, lime, plaster or similar;
    [0037] - preferably residual light loads, which enclose a considerable amount of air in its physical-chemical and molecular interior; selected from:
    [0038] - loads of plant origin,
    [0039] - loads of plastic origin,
    [0040] - loads of mineral origin, and
    [0041] - loads of organic origin or,
    [0042] - loads of multi-component residual post-formed products,
    [0043] - acrylic polymeric additives, polypropylene, carbon or similar reinforcing fibers and water;
    [0044] - optionally also, dyes and acrylic soluble oxidants such as iron sulfates, copper sulfate, walnut or the like and;
    [0045]
    [0046] c) Obtaining a new bio-product, object or element made by coating or encapsulating, micro-particular or set, of all kinds of various obsolete and residual containers, packaging and products, with one or several layers of said bio-mortar that covers them, waterproofs, insulates, protects and decorates totally or partially.
    [0047]
    [0048] This bio-mortar is also applicable in the coating of metal sheets, simple prefabricated panels, or compounds of various layers or thermo-insulating layers, of all types of products, on one or both sides, for their substitute use of other conventional mortar formulas used in the manufacture of various prefabricated and also applied or projected as coating of any object, ceilings, roofs, floors and walls.
    [0049]
    [0050] By way of illustration, loads of plant origin may be powder and crushed wood and cork; loads of plastic origin of: sawdust and crushed polystyrene, polyurethane, polyisocyanurates, phenolic foams and the like; charges of mineral origin of rock wool, fiberglass, carbon fiber or the like; charges of organic origin of leather powder or the like; and loads of multicomponent residual products, of a mixture of sawdust or crushed insulating material with small particles and metal chips from sawing or industrial cutting of thermo-insulating panels that combine insulating products (polyurethanes, polystyrenes, poly-isocyanurates, mineral wool, cork , phenolic foams, glass fibers, or the like) with metal veneers.
    [0051]
    [0052] In this case, the bio-products and bio-mortars made with them acquire, in addition to great wear resistance, anti-vandalism protection, etc., magnetic capacity for the subsequent non-mechanical fastening of any object by means of magnets incorporated in the elements to be fastened , to attach and to support, as well as to improve the capacity and strength of mechanical subjection by means of the direct anchorage of self-tapping screws, without the use of previous plugs.
    [0053] Depending on the type and specific application to which they are intended, by-products and residual products may undergo different types of processing.
    [0054]
    [0055] In an embodiment of the invention, said processing comprises the classification and microtriting and, if necessary, the screening of by-products and residual products intended to form a sustainable load for the manufacture of thermal, acrylic-cement and polymeric bio-mortars, previously to its mixing, coating or encapsulation to later compose the definitive sustainable bio-product.
    [0056]
    [0057] In a variant embodiment, it comprises the agglomeration, beating or compacting of the selected by-products and residual products, forming a mass prior to its encapsulation and global coating, as a cover or protective crust of polymeric eco-concrete reinforced with reinforcements, fibers, meshes , cables and slings, for the manufacture of large compact blocks and floating structural masses, of low or low draft, suitable for navigation and transport even in shallow waters, with which it is possible to reduce the equivalent to the weight of the water it displaces its volume, at a rate of approximately one kilogram per liter, the total weight of any cargo such as full or empty cisterns, marble blocks, concrete elements, rescued objects, etc., being able to travel immersed in water suspended perpendicularly from the center of gravity of said floating mass, charges that also contribute during its transfer to the stabilization Onion of the floating mass itself, all representing an accumulation of advantages compared to the transport of the same merchandise inside or on deck of traditional flotation systems by air or vacuum much more unstable.
    [0058]
    [0059] In another variant embodiment it comprises cutting, cutting or deformation of residual products of insulating blocks and panels based on polystyrenes, polyurethanes, polyisocyanurates, phenolic foams, mineral fibers or the like; the formation with said residual products of figures, volumes and various forms prior to their coating by partial or total immersion, projection, manual application, plaster, etc., with polymeric bio-mortars mineral, vegetable, organic or acrylic-cementitious and waterproof plastics ; which for its docility, fluidity and lightness, unlike conventional mortars that carry heavy loads of sand or silica, do not lift the support and can be used as a coating for all types of objects such as glasses, bottles and other objects including glass as well as all kinds of vertical or horizontal walls, including plastic and metal.
    [0060]
    [0061] In the case of processed by-products that include charges with mineral fiber particles such as rock wool, vegetable fibers such as coconut fiber, plastic or artificial fibers and also based on phenolic foams and the like, conveniently coated or encapsulated as a shell; The method of the invention comprises the cutting, division or subsequent fragmentation of said already coated by-products and the formation of two or more bodies as independent containers, with the absorbent and / or deformable interior applicable in agriculture, decoration, window dressing, trophies, numismatics and in a very special way in floristry and bio-gardening. These bodies, by way of receptacles, remain with an uncoated face, with an interior filled with porous material, being applicable as seedbeds for agriculture and in natural, artificial or hydroponic gardening; for example, in pots and vases for presentation and conservation of natural or artificial flower stalks, in urban gardens and other hydroponic ornamental elements for all kinds of horticultural products, florists in general or gardening, especially in vertical gardening, green covers or similar.
    [0062]
    [0063] When a part of the hydroponic product is left uncoated after the indicated cut-out, or if a part of it has been left on purpose uncoated, when this bare part is placed in contact with the ground or semi-buried in the ground, for example by way of Rock, next to a plant or shrub, then acts as an inverted reservoir or hydroponic reserve that stores for its subsequent absorption the excess water due to excess rain or irrigation, supplying it to the plant or bush regularly and gradually when the land is dried by wind, shortage of rain or heat, thereby achieving considerable savings in natural resources as valuable as water, time, effort and energy.
    [0064]
    [0065] In one embodiment, the method of the invention comprises the additive of the sustainable bio-mortar especially when by-products such as polyurethane sawdust and rock wool or the like are used, by means of natural oxides and pigments such as for example iron sulfate and copper sulfate, soils , walnut, acrylic dyes, colored earth or the like; to obtain more ecologically and sustainably, better resemblance to the rocks and natural marbles, being able to intermingle, also, masses of different cement-polymer colors to form veins in order to imitate marbles, such as the well-known arabesque gray, pearl gray, travertine marble or Marquina black, etc.
    [0066]
    [0067] This method allows to obtain prefabricated single-piece thermo-insulating pieces such as: panels, tiles, terraces, blocks, including large format, laminated, polychrome and compact totally at discretion and "a la carte", composed for example of decorative finishes similar to stone or marble natural, or of sustainable technical intersections based on metal bio-mortars, plastic bio-mortars, mineral and basaltic bio-mortars, plant bio-mortars etc., as well as metal intermediate elements such as sheets, meshes, etc. and any other type of thermal insulation panel such as polystyrene, polyurethane, polyisocyanurate, rock wool, cork, fiberglass etc., of format, thickness and density, also "on demand", which greatly facilitates the tasks of isolation, decoration, placement, handling, clamping and transport, in addition to reducing the time of execution and drying on site, and in addition to saving space, energy cost and final cost of the product in short.
    [0068]
    [0069] In the case of stratified panels and compact blocks, the different layers or strata can be composed, textured and colored completely at discretion and in accordance with high-end two-color and polychrome designs, resolution, performance, visual impact and diverse functionality.
    [0070]
    [0071] This method allows, therefore, to reuse residual products and organic by-products, as an additional load for the manufacture of organic bio-mortar based on an acrylic-polymer mixture with lime and / or cements, especially indicated for the even thermal coating of interior murals , all kinds of doors, furniture and equipment, artistic objects such as figures of all kinds, crafts, decoration and household items, thermal protection and decoration of glasses, vases, wine bottles, lamps, candle holders, among others.
    [0072]
    [0073] This method allows the replacement of conventional molds with deformable elements such as plastics, rubber membranes, fabrics and awnings of all kinds, to texture and delimit the desired shapes and perimeters of the bodies; covering with them any type of object or package, using empty holes, combining with sand or earth, preferably wet, air, water or any other type of fluid, obtaining in this way and at a low cost, the modeling and the definitive form, in an original, personalized and discretionary way, of the new bio-products.
    [0074]
    [0075] Preferred embodiment of the invention.
    [0076]
    [0077] Embodiment example 1:
    [0078]
    [0079] The recycling method of the invention comprises the previous classification, transformation-adaptation and possibly the volumetric modification of by-products or residual products, for example: plastic packaging, plastic, glass containers, packaging remains, remains and vegetable, organic by-products, botanicals, mixed compound residues, etc., and the subsequent partial or total coating with highly adhesive acrylic bio-mortars whose approximate dry composition comprises:
    [0080] - 33% on average based on cement, lime, plaster etc.,
    [0081] - 60% on average based on light loads, usually residual and sustainable, that contain a considerable amount of molecular air inside, for example: vegetable loads such as dust, fibers and crushed wood and cork, plastic loads such as sawdust of polystyrene, polyurethane, phenolic foams and the like, mineral fillers such as rock wool, fiberglass, carbon and the like, or organic fillers such as dust and leather fibers etc.,
    [0082] - 5% on average based on polymeric additives, polypropylene, carbon or similar reinforcing fibers and,
    [0083] - 2% on average based on dyes and oxidants such as iron sulfates, copper sulfate, walnut, etc.
    [0084]
    [0085] In the kneading of the sustainable bio-mortar, the precise amount of water is also used to obtain a soft or hard consistency, forming as a whole a kind of fireproof skin or bark, weatherproof, thermal, light, breathable , highly decorative and natural looking.
    [0086]
    [0087] To mean that, in many of the embodiments of the invention, the use of molds is not necessary, since a good part of the forms of the by-products and residual products such as plastic containers, Tetra Brik®-type containers and other packages, wrappings or miscellaneous packaging, awnings, rubber membranes, fabrics of jute and other textile elements etc. and no waste is generated either, since the small fractions of leftover products are crushed again to be reused as a new load for the production of bio-mortars and bio-mortars, also ecologically sustainable.
    [0088]
    [0089] Through an expert composition and selective placement of the different elements (containers, packaging, etc.) to be recycled, intermingled, bonded together and coated by means of the bio-mortar or bio-mortar described above, they can be used to shape and build large quantities and diversity of objects and practical elements of variable density and on demand, including all types of floating platforms on water, and other transport elements, stabilization, signaling, mooring, rescue, purification, provisioning, marine or river cleaning, as well as for any other marine or river construction, such as bridges and floating walkways, containment barriers or artificial reefs, etc., as well as other household, gardening and ornamental elements, light magnetic elements, etc.
    [0090]
    [0091] All these construction elements are also fully recyclable and can be used again in the future, prior to their new crushing, as a new load for the same purposes and objectives pursued by the present invention.
    [0092]
    [0093] Embodiment Example 2
    [0094]
    [0095] The eco-sustainable metal bio-mortar is normally obtained, but not exclusively, by means of multicomponent residual products, especially from the manufacturing, cutting and handling industry of thermal insulation panels that combine one or more insulating products with an exterior metal plating that covers them, decorates and protects. Said insulating products can be, for example, polyurethanes, polystyrenes, polyisocyanurates, mineral wool, cork, phenolic foams, glass fibers, or the like.
    [0096]
    [0097] In the phase of sawing or industrial cutting of said panels a joint mixture of sawdust of insulating material and small metal chips is produced.
    [0098] This mixture has a very difficult recycling process, usually ending up in generic controlled landfills, since metal smelters should not be admitted as a result of smoke and highly polluting gases that would occur.
    [0099]
    [0100] In this exemplary embodiment, this mixture is used as a substitute for the conventional sand of other mortars and mixed in proportions between 40% and 65% of the total dry volume, with 25% to 55% of materials fragile binders, such as cements, limes, plasters etc .; In addition to adding, in proportions between 2% and 10%, with respect to the weight of the binding materials binder, an acrylic binder based on natural or synthetic polymers and copolymers that coalesce it, they facilitate an excellent grip between the different elements between yes and with the support to adhere, providing impermeability and flexible traction to the bioproduct obtained, and can also be added, if necessary, reinforcement fibers of polypropylene, carbon, or the like.
    [0101]
    [0102] By increasing the amount of setting material and decreasing the substitute load of by-products and residuals or vice versa, the consistency and mechanical strength of the metal biomorter is increased or decreased. The variation of the percentage of acrylic polymers and copolymers with respect to the weight of the cement is a function of the type of difficulty of adhesion of by-product or residual used, as well as to improve the functions of waterproofing, plasticity, flexotraction etc. of the bioproduct. In order to increase the magnetic capacity of the metal biomorter, it is also possible to incorporate metal meshes embedded inside the plaster or lining, which will act at the same time as an added mechanical and vandal-proof reinforcement.
    [0103]
    [0104] The main properties of this mixture, in addition to its extreme resistance to wear and vandalism by all the metal components that it incorporates, consist in the fact that the coatings made with it, will have the magnetic capacity to be able to withstand any object that incorporates without any mechanical attachment. one or more magnets, so that used both inside or back of prefabricated panels, or as a bio-mortar in the coating of all types of walls such as ceilings, floors and walls, will avoid the use of studs and fixing nails conventional mechanics, allowing its absolute mobility and position, being able to be fratasado, scraped, polished, repainted and decorated like any other type of coating conventional. Likewise, it can also be used in industrial floors where high wear resistance is intended.
    [0105]
    [0106] Once the nature of the invention has been sufficiently described, as well as a preferred embodiment, it is stated for the appropriate purposes that the materials, shape, size and arrangement of the described elements may be modified, provided that this does not imply an alteration. of the essential features of the invention that are claimed below.
    权利要求:
    Claims (7)
    [1]
    1. - Eco-sustainable method of recycling by encapsulation, diversification and reuse, of by-products or various residual products; characterized in that it comprises:
    a) a preprocessing of the by-products or residual products, which includes at least one of the following operations: selection, volumetric transformation and cutting or deformation thereof by any means;
    b) the preparation of an ecologically sustainable polymeric acrylic-cementitious bio-mortar encapsulation, comprising:
    - a fragile binder product, cement, lime, plaster or similar;
    - preferably residual light loads, which enclose a considerable amount of air in its physical, chemical and molecular interior; selected from:
    - loads of plant origin,
    - loads of plastic origin,
    - loads of mineral origin,
    - loads of organic origin,
    - loads of multi-component residual post-formed products, such as a mixture consisting of sawdust of insulating material and small particles and metal chips;
    - acrylic polymeric additives, polypropylene, carbon or similar reinforcing fibers and water.
    - optionally, acrylic dyes and oxidizers such as iron sulfates, copper sulfate, natural pigments, earth, walnut or similar;
    c) Obtaining a new bio-product made by coating or encapsulating, individual or set of all kinds of various packaging, packaging and residual products, with one or several layers of bio-mortar that covers, waterproofs, insulates, protects and decorate totally or partially.
    [2]
    2. - Method according to claim 1, characterized in that it comprises the classification, micro-crushing and, if necessary, the screening of by-products and residual products intended to form a sustainable load for the manufacture of bio-mortars thermal, acrylic-cementitious and polymeric, prior to mixing, coating or encapsulating to subsequently compose the definitive sustainable bio-product.
    [3]
    3. - Method, according to claim 1, characterized in that it comprises the agglomeration, beating or compacting of the selected by-products and residual products, forming a mass prior to encapsulation and overall coating as a cover or protective crust of reinforced polymeric concrete-concrete with reinforcements, fibers, meshes, cables and slings, for the manufacture of large compact blocks and floating structural masses of low or low draft, suitable for navigation and transport even in shallow water.
    [4]
    4. - Method according to claim 1, characterized in that it comprises cutting, exploding or deformation of residual products of insulating blocks and panels based on polystyrenes, polyurethanes, polyisocyanurates, phenolic foams, mineral fibers or the like; the formation with said residual products of various figures, volumes and shapes prior to their manual coating, by partial or total immersion, projection, plaster, etc., with polymeric bio-mortars mineral, vegetable, organic or acrylic-cement and waterproof plastics.
    [5]
    5. - Method, according to claim 1, characterized in that it comprises the subsequent cutting, division or fragmentation of objects and elements made with loads of mineral fibers such as rock wool, vegetable fibers such as coconut fiber, plastic fibers or the like as well as base of phenolic foams and the like, once already coated or encapsulated; and thus the formation of two or more bodies as independent containers with their porous or deformable interior, applicable in agriculture, decoration, window dressing, trophies, numismatics and in a very special way in floristry and bio-gardening.
    [6]
    6. - Method according to any of the preceding claims; characterized in that it comprises the additive of the bio-mortar by oxides and natural pigments such as iron sulfate and copper sulfate, walnut, acrylic dyes, colored earth or the like.
    [7]
    7. - Method according to the preceding claims; characterized in that it includes the replacement of conventional molds with deformable elements such as plastics, rubber membranes, fabrics and awnings of all kinds, to texture and delimit the desired shapes and perimeters of the bodies, covering with them any type of object or bulk, using empty holes and holes, combining with sand or earth, preferably wet, as well as air, water and any other type of fluid or gaseous element.
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    同族专利:
    公开号 | 公开日
    ES2731686B2|2020-03-23|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    WO2013151439A1|2012-04-05|2013-10-10|Cdem Minerals Group B.V.|Dry admixture for concrete, mortar and cement and method of preparing the|admixture|
    WO2014194386A1|2013-06-07|2014-12-11|Fcc - Fornecedora Componentes Químicos E Couros Ltda.|Polymeric mortar|
    法律状态:
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    优先权:
    申请号 | 申请日 | 专利标题
    ES201830472A|ES2731686B2|2018-05-17|2018-05-17|ECO-SUSTAINABLE METHOD OF RECYCLING BY ENCAPSULATION, DIVERSIFICATION AND REUSE, OF MISCELLANEOUS BY-PRODUCTS OR RESIDUAL PRODUCTS.|ES201830472A| ES2731686B2|2018-05-17|2018-05-17|ECO-SUSTAINABLE METHOD OF RECYCLING BY ENCAPSULATION, DIVERSIFICATION AND REUSE, OF MISCELLANEOUS BY-PRODUCTS OR RESIDUAL PRODUCTS.|
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