PatentDe  


Dokumentenidentifikation EP1349452 29.12.2005
EP-Veröffentlichungsnummer 0001349452
Titel IN-SITU BESCHLAGEN VON PFERDEN
Anmelder Vettec Inc., Oxnard, Calif., US
Erfinder ROVELLI, Frank, Oxnard, US
Vertreter derzeit kein Vertreter bestellt
DE-Aktenzeichen 60207524
Vertragsstaaten AT, BE, CH, CY, DE, DK, ES, FI, FR, GB, GR, IE, IT, LI, LU, MC, NL, PT, SE, TR
Sprache des Dokument EN
EP-Anmeldetag 18.03.2002
EP-Aktenzeichen 027214840
WO-Anmeldetag 18.03.2002
PCT-Aktenzeichen PCT/US02/08444
WO-Veröffentlichungsnummer 0002080666
WO-Veröffentlichungsdatum 17.10.2002
EP-Offenlegungsdatum 08.10.2003
EP date of grant 23.11.2005
Veröffentlichungstag im Patentblatt 29.12.2005
IPC-Hauptklasse A01L 11/00
IPC-Nebenklasse A01L 5/00   

Beschreibung[en]
Technical Field

This invention relates to the art of horseshoeing. More particularly, the invention relates to forming horseshoes in place, i.e. in situ, rather than fabricating the shoe away from the animal and tacking it to the hoof. More broadly, the invention relates to the addition to hoofs of various animals needing hoof protection. More particularly, the invention provides the benefits of shoeing to horses and other animals in an especially convenient and effective manner. The invention provides, for example, with respect to horseshoes, for the shoeing of horses with a resin composition that sets up instantly in situ on the horse's hoof in the near form of a horseshoe and is then trimmed to a perfect shape. The invention enables the periodic renewal of horseshoes with a minimum of effort, readily affords local variation in shoe thickness to compensate for hoof irregularities, and ensures an effective protection for the horse's hoof.

Background Art

Horseshoes have been fabricated of metals for centuries and more recently from synthetic materials, but always by prefabricating the shoe and then applying the prefabricated shoe onto the horse's hoof. See, for example, USP 5,699,861 to Sigafos where a kit for horseshoeing is described. The problems of prefabricated horseshoes, whether of metal or plastic is that the shape of the hoof to be shod varies making the application of a prefabricated shoe a process of trial and error, and a highly skilled and expensive to obtain art. Also, some hoofs need a thicker section in one place than in another. It is economically infeasible to market or inventory all the possibilities that may be encountered.

US 3,285,346 describes the use of a liquid resin and a mold to form a horse shoe on the hoof of a horse. The resin is applied to the mold and cured. A similar method is disclosed in US 4,765,411. However, the use of a mold that has to be applied to the horses hoof is difficult, and curing of a resin often involves high temperatures that will not be tolerated by the horse.

US 5,681,350 describes a method for repairing the side wall of a hoof. A mixture of a particulate matter and a catalytic hardening polymeric resin which is described to have a viscosity similar to wet modeling clay is used to form a prosthesis on the hoof. This document does not a im at horse shoeing, n or is it suggested that the material would be suitable for forming permanent horse shoes.

US 5,213,163 describes a glue on horse shoe of urethane resin. This horseshoe is semi hard having a Shore D hardness of above 50. This is a conventional shoe in the sense that it is a shoe when it first comes into contact with the hoof, it is fitted to the horses hoof by means of a gap filling adhesive. Although the shoe is surface conformed to the hoof by heating to a certain softness when gluing it needs the gap filling adhesive for precise fitting.

Disclosure of Invention

What is needed is a more flexible approach, one that allows customizing of the shoes to the hoof.on site without onerous or costly effort. It is accordingly an object of the invention to provide an in situ shoeing method. It is a further object to provide a system for the creation on the hoof itself of the shoe. It is a further object to reduce inventory requirement to merely a variously applicable resin system that is applied to the hoof in custom fashion without custom inventory. A further object of the invention is to deposit onto a prepared hoof shoeing surface a resin mass, that may comprise an intimate admixture of reactive resin components, in a profile approximating the intended shoe, that is malleable albeit non-flowing when applied, and modifiable to the desired exact contour to achieve any thickness, any thickness variation along the extent of the shoe, and of course a precise registration of the deposited resin system with the hoof contour without difficult bending of strong, prefabricated materials. It is a still further object to provide a mass resin system typically comprising A and B sides of a resin in the form of reactive thermosetting resin precursors, e.g. comprising urethane resin precursors, that is thixatroped to have a consistency allowing the resin during reaction to a formed, cured or hardened to a state to stand on the hoof shoeing surface without excessive flow off the surface. A further object is the provision of an animal or horse shoe of an intended profile comprising the resin mass in substantially the intended profile in situ on a horse hoof surface, more particularly a synthetic organic resin horseshoe formed in situ on a horse hoof surface. Other objects include: forming while shoeing a moisture barrier on the hoof surface, through the adhesion of the applied resin mass to the hoof surface material; providing a possibility for repairing shoed hooves by addition of more resin mass where wear has occurred, which is effective because the resin mass in many embodiments will adhere to its previously cured self; preventing the horse from pulling a shoe, i.e. removing a shoe on an adjacent hoof with another hoof through a purchase gained at the so-called lip protruding rearwardly from the conventional horseshoe by eliminating the lip protrusion altogether with careful tailoring of the shoe so as to be narrow on the hoof; equalizing pressure on the hoof all about the hoof surface as an improvement over the use of nails which become as many as seven or more points of pressure; enabling shoeing of horses whose hooves are worn too much to tolerate nailing, but will accept a shoe formed in situ; adding spring to the horse's step through the resiliency of the in-situ-formed horseshoe, the profile of which can be modified to add a spring function; improving traction by customizing the shoe bottom surface to the anticipated terrain; adding color at the shoe, bodily or in accents, or other optical effects including patterns and glitter to reflect the stable that trained the horse, or a cause or event; and to have or provide a layer of resiliency at the hoof for comfort and longevity of the horse.

These and other objects of the invention to become apparent hereinafter are realized in the method for building a horseshoe of an intended shape in situ, including cleaning the surface of the shoe area of horse hoof of debris, shaping a temporarily generally malleable mass of resin on the cleaned hoof surface into generally a horseshoe-shape, and locally modifying the exposed surfaces of the horseshoe mass to conform to the final intended horseshoe shape on the shoe area surface after general malleability in the resin is lost.

In this and like embodiments, typically, the resin selected is one that self-adheres to the shoe area surface, and there is included also precoating the shoe area surface under the mass with a thin layer of the mass or similar resin having less than 25% of the depth of the intended horseshoe shape, selecting as the resin a reaction product of thermosetting resin precursors, selecting as the resin precursors thermosetting urethane resin precursors.

In this and like embodiments, typically, the method further includes locally reshaping the horseshoe mass to conform to the intended horseshoe shape on the shoe area surface, selecting as the precoating resin the same resin as the shaped mass resin.

In one embodiment, according to claim 1 the invention provides a method for building a horseshoe of an intended shape in situ, including cleaning the surface of the shoe area of a horse hoof of debris, collecting an unconfined malleable resin mass beyond the shoe area surface, applying the mass onto the cleaned hoof surface in a generally horseshoe-shaped form, and then locally modifying the exposed surfaces of the horseshoe mass to conform to the final intended horseshoe shape on the shoe area surface.

According to preferred embodiments the method further includes selecting as the resin mass a mass that self-adheres to the shoe area surface, and selecting as the resin mass a mass comprising a mixture of thermosetting resin precursors, such as thermosetting urethane resin precursors.

In a further embodiment, according to claim 5 the invention provides a method for building an animal shoe of an intended shape in situ, including cleaning the surface of the shoe area of debris, depositing onto the cleaned hoof surface a flowable shoe preform comprising a resin mass having a depth and width of profile generally conforming to the intended shoe shape in the shoe area surface adhering relation, reducing the mass to a non-flowable state to retain substantially all the mixture on the shoe area surface, and then locally mechanically modifying the mass to modify its profile to conform to the final intended shoe shape on the shoe area surface.

According to this embodiment the method includes selecting as the mass a mass that self-adheres to the shoe area surface. According to preferred embodiments, the method includes selecting as the mass a mass that comprises reactive resin precursors in intimate admixture in a common vessel, the mass being reduced to a nonflowable state by reaction of the precursors, such as thermosetting resin precursors, e.g. thermosetting urethane resin precursors such as diphenylmethane diisocyanate, polyol, a thixatroping amine, such as a thixatroping primary or secondary amine, like meta xylene diamine.

The invention further includes the products of the foregoing methods.

In a further embodiment, there is provided a method for building a horseshoe in situ including cleaning the surface of the shoe area of horse hoof of debris, depositing onto the cleaned hoof surface a flowable horseshoe preform comprising an intimate curable mixture of urethane resin precursors comprising diphenylmethane diisocyanate and a polyoxyproplyene oxide polyol and meta xylene diamine at a depth and width profile greater than the intended horseshoe shape at a viscosity to remain on the surface, curing the mixture to a non-flowable mass in less than one minute, and shaping the horseshoe preform to reduce its profile to a final intended horseshoe shape on the surface.

In another aspect the invention provides a moisture-proofing of the shoed hoof surface, the method including protecting a horse hoof from moisture accumulation between shoe and hoof, including cleaning the hoof surface of debris and forming on the cleaned hoof an adherent resin mass that adheres to the hoof surface in moisture excluding relation.

In other aspects the invention provides the method of protecting a horse hoof from uneven pressure on the hoof from horseshoe, including clearing from the hoof all nails and previous shoe, and forming on the cleaned hoof an adherent resin mass that adheres to the hoof surface in shoe-forming relation, the method of maintaining a horse hoof shoe against wearing from an intended shape, including cleaning the shoe surface of debris, and restoring the intended shape to the shoe through the added application of an adherent resin mass that adheres to the hoof surface, the method of increasing the stepping comfort of a horse, including providing and maintaining as the horse hoof shoe a shoe comprising a resin having a resilience to be reduced temporarily in vertical profile when the horse puts its weight upon the shoe, and a synthetic organic resin hoof shoe hardened in situ on a hoof, the hoof-shaped resin exhibiting an optical effect other than its natural appearance.

Brief Description of Drawings

The invention will be further described in conjunction with the attached drawings in which:

  • Fig. 1 is an oblique view of the troweling application of a malleable resin mass to provide a horseshoe preform onto a hoof surface;
  • Fig. 1A is taken on line 1A - 1A in Fig. 1;
  • Fig. 2 is a plan view of the cured hoof shoe preform being modified to its intended shape; and,
  • Fig. 3 is a view like Fig. 2 showing further modification of the hoof shoe.

Best Mode for Carrying Out the Invention

The invention provides the ultimate in shoeing convenience. A resin mass that is malleable, that is shapeable by pushing with a hand held spatula, but so viscous as to stand, at least temporarily, as deposited and not flow freely from the hoof surface, is deposited by trowel, by hand or other means from a mixing vessel such as a bucket onto the shoeing area of the hoof. The mass is deposited in approximately the intended shoe shape and when solidified by solvent evaporation, cure, setting up, or hardening from a more fluid state to be nonmalleable or rigid is trimmed to the intended shoe shape. The use of an in situ formed shoe eliminates the need for an inventory of various shoes, and the need for the farrior's laborious fashioning of metal to just the right form. If the hoof is less than perfect, or the horse in need of a particular kind of shoe, the amount and disposition of the resin mass can be tailored by a simple adjustment in the application steps to compensate. The invention enables the customizing of the shoe to the horse in a remarkably easy manner.

With reference now to the drawings in detail in Figs. 1 and 1A, hoof 10 has a surface 26 defining a shoe area 28. Shoe area 28 is provided with a shoe 12 formed immediately on the hoof, i.e. in situ, from a mass 14 of resin deposited from a spatula or trowel 15 onto the shoe area 28.

The invention method for building in situ a horseshoe 12 of an intended shape 24 (shown in Figs. 2 and 3), includes upturning the horse hoof 10 for treatment, and cleaning the surface 26 of the shoe area 28 of horse hoof of debris. A shoe preform 32 is formed on the shoe area 28 by depositing onto the surface 26 a generally malleable mass 14 of resin, shaping the resin mass into generally a shoe shape (preform 32) having a suitable depth, e.g. 1,27 cm (S inch), and width, e.g. 2,54 cm (1 inch), of profile 30, see Fig. 1A. Preform profile 30 generally conforms to the intended horseshoe shape 24. Suitably, the mass 14 self-adheres, as with a urethane resin to the shoe area surface 26. The mass 14 loses malleability through loss of solvent, cooling in the case of a hot melt resin mass, curing or hardening under any of various regimes including cure by moisture, heat, light, catalysts, etc., suitably at ambient temperatures, preferably of 18,3 to 29,4 °C (65 to 85 °F) for the thermosetting resin system exemplified below. Mass 14 having the profile 30 of the preform 32 can harden or cure to a non-malleable form 36 by the just mentioned processes or by reaction of the resin precursors before substantial portions of the mass 14 flow from the profile 30 shape. In some cases the mass 36 is deliberately extended as a skirt 37 to cover the immediately adjacent hoof areas 39 beyond the hoof surface 26.

Following loss of malleability, which is accomplished in one or two minutes, or faster, such as 30 seconds, the preform 32 is locally shaped with a rasp 38 or other tool to have the intended shoe shape 24 with the surface finish and perimeter contour desired, see Figs. 2 and 3.

Epoxy, vinyl ester, acrylic, polyester, and other resins formulations that set up or cure quickly without animal damaging exotherms, that are tough, that are hoof adherent, and are otherwise suitable are likely candidates for use in the invention, in addition to the urethane resins mentioned herein. Suitable resin systems herein are resins having the requisite strength and forming properties and include, among thermosetting resins, epoxy resins, vinyl ester resins, such as the auto-cure or light-cure resin products of diacrylates, and dimethacrylates of Bisphenol-A ethoxylate resins, corresponding bis-F resins, the auto-cure or light-cure resin products of acrylic functionality, unsaturated polyester resin oligomers, including those based on the condensation products of maleic and phthalic anhydrides or acids of glycols, polyester resins in combinations of monomers including styrene, divinylbenzene, ethyl acrylate, methylmethacrylate, and other acrylates, and auto-curing resins above that are catalyzed by various peroxides and promoted by various amines. Thermoplastics such as polyamides, acrylonitrile butadiene styrene polymers, polycarbonates, polyphenylene oxides, polysulfones, polyphenylene sulfides, and fluoropolymers can be used where the strength and other properties are adequate to horseshoe use.

Preferred are polyurethane polymers, thermosetting synthetic organic resins formed from A and B sides comprising reactive component precursors of the resin. Such resins cure rapidly, are low in shrinkage, are hard and tough, are formable with tools such as rasps in less than two minutes, preferably, do not have excessive exotherms that might injure or discomfort the animal, and self-adhere to the surface 26. Preferably, these resins are reaction products of reactive precursors that can be mixed simply as reactive resin precursors to an intimate admixture. Preferred urethane resins are formed from reactive precursors of diisocyanates, e.g. aliphatic, and preferably aromatic diisocyanates, on one side and polyols, either aliphatic or aromatic polyols, on the other, with other additives that act as coupling agents, such as silanes in amounts from 0.1 to 5% by weight, that extend the polymer chains, add thixatropy, such as amines, and/or fumed silicas, that catalyze the reaction. Preferred urethane resins include thixatropic compositions having the side A reactive resin precursor diphenylmethane diisocyanate and as the side B reactive resin precursor polyoxypropylene oxide polyether polyols and meta xylene diamine, a coupling agent such as one or more silanes at about 3% by weight of the reaction mixture, Quadrol, for improved snap and rasping qualities, and thixatroping agents.

If desired, there can be a precoating of the shoe area surface with a thin layer of the resin mass 14, typically having less than 25% and as little as 5 to 15% of the profile 30 depth of the intended horseshoe shape 24. Such a lesser mass of reactants will have a lower exotherm than the full profile depth, assuming the same reactants. The thin layer is at least partially cured before depositing additional mass 14 onto the thin layer.

Further details on suitable urethane resins prepared from one or more isocyanates, catalysts, various polyols, and amines are disclosed in USP 4,869,400, provided the foregoing criteria are met.

Example

A reactive urethane resin mixture typically useful in the invention is prepared from two parts (A and B sides) of equal volume in a suitable vessel such as a bucket, or in a dual cartridge dispenser in' which dual pistons on a common yoke extrude the separate reactive components through a manifold and into a mix tip comprising a series of baffles arranged to cut and recombine the mixing materials as they progress through the mix tip. All parts and percentages are by weight:

Part A

Component Parts by Weight Isocyanate Prepolymer (Rubinate 1660 or MDI) 78. D.B. Castor Oil 21. Silane (Silquest A-1310) 1. Silane A-187 2.

Part B

Component Parts by Weight Polyol (Multranol 3901) 54. Polyol (Multranol 4012 26. Quadrol (N'N'N'N'-tetrakis(2-hydroxyethyl or propyl ethylene diamine) 18. MXDA (1,3-benzene diamino methane) 2.6 Catalyst (Coscat 83) 0.25
The reaction mass comprising the above sides mixed together is applied by trowel onto the horse hoof that has been cleaned and otherwise prepared to receive the in-situ horseshoe.

The invention thus provides a method for building a horseshoe of an intended shape in situ, using a malleable resin mass as the horseshoe preform, the mass having a depth and width of profile generally conforming to the intended horseshoe shape, adhering the mixture to the shoe area surface, rendering the mass non malleable before substantial portions of the mixture flows from the shoe area surface, and then locally shaping the horseshoe preform to modify its deposited profile to conform to the final intended horseshoe shape on the shoe area surface. The invention further provides the product of the method and more broadly an in situ formed animal shoe in substantially the intended profile in situ on a horse hoof surface.

The foregoing objects are thus met.


Anspruch[de]
  1. Verfahren zum Aufbau von Hufeisen (12) mit einer vorbestimmten Form (24) in situ, umfassend die Schritte Säubern der Oberfläche (26) der Hufeisenfläche (28) eines Pferdehufs (10) von Fremdkörpern, Sammeln einer uneingeschränkt plastischen Harzmasse (14) unterhalb der Oberfläche (26) der Hufeisenfläche, Aufbringen der Masse (14) auf die gesäuberte Oberfläche (26) der Hufeisenfläche in einer ungefähr Hufeisenförmigen Form und anschließend lokales Bearbeiten der äußeren Oberflächen der Hufeisenmasse, so dass sie der endgültigen vorbestimmten Hufeisenform auf der Oberfläche (26) der Hufeisenfläche entspricht.
  2. Verfahren gemäß Anspruch 1, umfassend als weiteren Schritt Auswählen einer auf der Oberfläche (26) der Hufeisenfläche selbstklebenden Masse als Harzmasse (14).
  3. Verfahren gemäß Anspruch 1, umfassend als weiteren Schritt Auswählen einer Masse enthaltend eine Mischung thermisch härtender Harzausgangsmaterialien als Masse (14).
  4. Verfahren gemäß Anspruch 3, umfassend als weiteren Schritt Auswählen von thermisch härtenden Urethanharzausgangsmaterialien als Harzausgangsmaterialien.
  5. Verfahren zum Aufbau von Hufeisen (12) mit einer vorbestimmtem Form (24) in situ, umfassend die Schritte Säubern der Oberfläche (26) der Hufeisenfläche (28) von Fremdkörpern, Aufbringen einer plastischen Hufeisenvorform (32) auf der Hufoberfläche (26) in einer an der Oberfläche der Hufeisenfläche (26) haftenden Verbindung, wobei die Hufeisenvorform (32) eine Harzmasse (14) umfasst, die auf der Oberfläche der Hufeisenfläche selbstklebend ist und deren Profil eine Tiefe und Breite aufweist, die ungefähr der vorbestimmten Hufeisenform (24) entspricht, Umwandeln der Masse (14) in einen nicht-plastischen Zustand, so dass im Wesentlichen die gesamte Mischung (14) auf der Oberfläche (26) der Hufeisenfläche verbleibt, und anschließend lokales mechanisches Bearbeiten der Masse (14), so dass deren Profil (30) der endgültigen vorbestimmten Hufeisenform (24) auf der Oberfläche (26) der Hufeisenfläche entspricht.
  6. Verfahren gemäß Anspruch 5, umfassend als weiteren Schritt Auswählen einer Masse umfassend reaktionsfähige Harzausgangsmaterialien in inniger Mischung in einem gemeinsamen Gefäß als Harzmasse (14), wobei die Masse durch Reaktion der Ausgangsmaterialien in den nicht-plastischen Zustand umgewandelt wird.
  7. Verfahren gemäß Anspruch 6, umfassend als weiteren Schritt Auswählen von thermisch härtenden Harzausgangsmaterialien als Harz.
  8. Verfahren gemäß Anspruch 7, umfassend als weiteren Schritt Auswählen von thermisch härtenden Urethanharzausgangsmaterialien als Harzausgangsmaterialien.
  9. Verfahren gemäß Anspruch 8, umfassend als weiteren Schritt Auswählen eines Harzausgangsmaterials umfassend Diphenylmethandiisocyanat als reaktives Seite A Harzausgangsmaterial.
  10. Verfahren gemäß Anspruch 8, umfassend als weiteren Schritt Auswählen eines Harzausgangsmaterials umfassend ein Polyol als reaktives Seite B Harzausgangsmaterial.
  11. Verfahren gemäß Anspruch 8, umfassend als weiteren Schritt Auswählen eines Harzausgangsmaterials umfassend ein thixotropierendes Amin als reaktives Seite B Harzausgangsmaterial.
  12. Verfahren gemäß Anspruch 8, umfassend als weiteren Schritt Auswählen eines Harzausgangsmaterials umfassend ein thixotropierendes primäres oder sekundäres Amin als reaktives Seite B Harzausgangsmaterial.
  13. Verfahren gemäß Anspruch 8, umfassend als weiteren Schritt Auswählen eines Harzausgangsmaterials umfassend ein thixotropierendes Amin enthaltend meta-Xyloldiamin als reaktives Seite B Harzausgangsmaterial.
  14. Verfahren gemäß Anspruch 8, umfassend als weiteren Schritt Einbringen eines Haftvermittlers enthaltend ein Silan in Seite A und/oder Seite B.
  15. Verfahren gemäß Anspruch 14, umfassend weiterhin eine Zugabe des Silans in Mengen von etwa 0,1 Gew.-% bis etwa 5 Gew.-% in jede Seite, in der es vorliegt.
  16. Verfahren gemäß Anspruch 4, umfassend weiterhin Vorhalten von pyrogener Kieselsäure in der reaktiven Harzmischung.
  17. Vefahren gemäß Anspruch 4, umfassend weiterhin Einbringen von Quadrol in die reaktive Harzmischung.
  18. Verfahren gemäß Anspruch 10, umfassend als weiteren Schritt Auswählen eines Harzausgangsmaterials umfassend Diphenylmethandiisocyanat als reaktives Seite A Harzausgangsmaterial.
Anspruch[en]
  1. A method for building a horseshoe (12) of an intended shape (24) in situ, including cleaning the surface (26) of the shoe area (28) of a horse hoof (10) of debris, collecting an unconfined malleable resin mass (14) beyond said shoe area surface (26), applying said mass (14) onto the cleaned hoof surface (26) in a generally horseshoe-shaped form, and then locally modifying the exposed surfaces of said horseshoe mass to conform to said final intended horseshoe shape (24) on said shoe area surface (26).
  2. The method according to claim 1, including also selecting as said resin mass (14) a mass that self-adheres to said shoe area surface (26).
  3. The method according to claim 1, including also selecting as said resin mass (14) a mass comprising a mixture of thermosetting resin precursors.
  4. The method according to claim 3, including also selecting as said resin precursors thermosetting urethane resin precursors.
  5. A method for building an animal shoe (12) of an intended shape (24) in situ, including cleaning the surface (26) of the shoe area (28) of debris, depositing onto the cleaned hoof surface (26) a flowable shoe preform (32) comprising a resin mass (14) that self-adheres to said shoe area surface having a depth and width of profile generally conforming to said intended shoe shape (24) in said shoe area surface (26) adhering relation, reducing said mass (14) to a non-flowable state to retain substantially all said mixture (14) on said shoe area surface (26), and then locally mechanically modifying said mass (14) to modify its profile (30) to conform to said final intended shoe shape (24) on said shoe area surface (26).
  6. The method according to claim 5, including also selecting as said mass (14) a mass that comprises reactive resin precursors in intimate admixture in a common vessel, said mass being reduced to a nonflowable state by reaction of said precursors.
  7. The method according to claim 6, including also selecting as said resin precursors thermosetting resin precursors.
  8. The method according to claim 7, including also selecting as said reactive resin precursors thermosetting urethane resin precursors.
  9. The method according to claim 8, including also selecting as a side A reactive resin precursor a precursor comprising diphenylmethane diisocyanate.
  10. The method according to claim 8, including also selecting as a side B reactive resin precursor a precursor comprising a polyol.
  11. The method according to claim 8, including also selecting as a side B reactive resin precursor a precursor comprising a thixatroping amine.
  12. The method according to claim 8, including also selecting as a side B reactive resin precursor a precursor comprising a thixatroping primary or secondary amine.
  13. The method according to claim 8, including also selecting as a side B reactive resin precursor a precursor comprising a thixatroping amine comprising meta xylene diamine.
  14. The method according to claim 8, including also incorporating into side A and/or side B a coupling agent comprising a silane.
  15. The method according to claim 14, including also adding said silane in amounts from about 0.1% to about 5% by weight in each said side where present.
  16. The method according to claim 4, including also maintaining in said reactive resin precursor mixture fumed silica.
  17. The method according to claim 4, including also incorporating into said reactive resin precursor mixture Quadrol.
  18. The method according to claim 10, including also selecting as a side A reactive resin precursor a precursor comprising diphenylmethane diisocyanate.
Anspruch[fr]
  1. Procédé de fabrication in situ d'un fer à cheval (12) d'une forme déterminée (24), comprenant un nettoyage de débris de la surface (26) de la zone pour fer à cheval (28) d'un sabot de cheval (10), un ramassage d'une masse résineuse malléable non confinée (14) au-delà de ladite surface de zone pour fer à cheval (26), une application de ladite masse (14) sur la surface de sabot nettoyée (26) en une forme présentant globalement la configuration d'un fer à cheval, et ensuite localement une modification des surfaces exposées de ladite masse en fer à cheval pour épouser ladite forme en fer à cheval déterminée finale (24) sur ladite surface de zone pour fer à cheval (26).
  2. Procédé selon la revendication 1, comprenant également une sélection comme dite masse résineuse (14) d'une masse qui adhère automatiquement à ladite surface de zone pour fer à cheval (26).
  3. Procédé selon la revendication 1, comprenant également une sélection comme dite masse résineuse (14) d'une masse comprenant un mélange de précurseurs de résine thermodurcissables.
  4. Procédé selon la revendication 3, comprenant également une sélection comme dits précurseurs de résine de précurseurs de résine uréthane thermodurcissables.
  5. Procédé de fabrication in situ d'un fer d'animal (12) d'une forme déterminée (24), comprenant un nettoyage de débris de la surface (26) de la zone pour fer (28), un dépôt sur la surface de sabot nettoyée (26) d'une préforme de sabot fluide (32) comprenant une masse résineuse (14) qui adhère automatiquement à ladite surface de zone pour fer ayant une profondeur et une largeur d'un profil épousant généralement ladite forme de fer déterminée (24) dans ladite relation d'adhérence à la surface de zone pour fer (26), une réduction de ladite masse (14) à un état non fluide pour retenir substantiellement tout ledit mélange (14) sur ladite surface de zone pour fer (26), et ensuite localement une modification de façon mécanique de ladite masse (14) afin de modifier son profil (30) pour épouser ladite forme de fer déterminée finale (24) sur ladite surface de zone pour fer (26).
  6. Procédé selon la revendication 5, comprenant également une sélection comme dite masse (14) d'une masse qui comprend des précurseurs de résine réactifs dans un mélange intime dans un récipient commun, ladite masse étant réduite à un état non fluide par réaction désdits précurseurs:
  7. Procédé selon la revendication 6, comprenant également une sélection comme dits précurseurs de résine de précurseurs de résine thermodurcissables.
  8. Procédé selon la revendication 7, comprenant également une sélection comme dits précurseurs de résine réactifs de précurseurs de résine uréthane thermodurcissables.
  9. Procédé selon la revendication 8, comprenant également une sélection comme précurseur de résine réactif côté A d'un précurseur comprenant du diphénylméthanediisocyanate.
  10. Procédé selon la revendication 8, comprenant également une sélection comme précurseur de résine réactif côté B d'un précurseur comprenant un polyol.
  11. Procédé selon la revendication 8, comprenant également une sélection comme précurseur de résine réactif côté B d'un précurseur comprenant une amine thixotropante.
  12. Procédé selon la revendication 8, comprenant également une sélection comme précurseur de résine réactif côté B d'un précurseur comprenant une amine thixotropante primaire ou secondaire.
  13. Procédé selon la revendication 8, comprenant également une sélection comme précurseur de résine réactif côté B d'un précurseur comprenant une amine thixotropante comprenant de la méta-xylène diamine.
  14. Procédé selon la revendication 8, comprenant également une incorporation dans le côté A et/ou le côté B d'un agent de couplage comprenant un silane.
  15. Procédé selon la revendication 14, comprenant également un ajout dudit silane en des quantités d'environ 0,1% à environ 5% en poids dans chaque dit côté où il est présent.
  16. Procédé selon la revendication 4, comprenant également un maintien de silice pyrogénée dans ledit mélange de précurseur de résine réactif.
  17. Procédé selon la revendication 4, comprenant également une incorporation de Quadrol dans ledit mélange de précurseur de résine réactif.
  18. Procédé selon la revendication 10, comprenant également une sélection comme précurseur de résine réactif côté A d'un précurseur comprenant du diphénylméthanediisocyanate.






IPC
A Täglicher Lebensbedarf
B Arbeitsverfahren; Transportieren
C Chemie; Hüttenwesen
D Textilien; Papier
E Bauwesen; Erdbohren; Bergbau
F Maschinenbau; Beleuchtung; Heizung; Waffen; Sprengen
G Physik
H Elektrotechnik

Anmelder
Datum

Patentrecherche

Patent Zeichnungen (PDF)

Copyright © 2008 Patent-De Alle Rechte vorbehalten. eMail: info@patent-de.com