WO2013174534A1 - Hoof protection system for horses or similar ungulates - Google Patents

Abstract

Disclosed is a hoof protection system (20, 120) for horses or similar ungulates, comprising a particularly horseshoe-shaped connecting shoe (14, 114) that can be attached to the hoof, and a frog segment (1, 101) which can be attached to the two end regions of the connecting shoe, bridges said two end regions, and includes two connecting legs (2a, 2b; 102a, 102b) and a frog section (3, 103). The two connecting legs can respectively be connected to an end region of the connecting shoe, while the frog section is arranged between the connecting legs to contact the frog of a horse or similar ungulate.

Description

 Hoof protection system for horses or similar ungulates

The present invention relates to a Hufsehutzsystem for horses or the like ungulates with a attachable to the hoof, in particular horseshoe-shaped connecting iron.

Horseshoes in the form of horseshoes have long been known. In addition to the conventional horseshoes, hoof-riding devices are also known which have such a hoof-mountable horseshoe-shaped carrier bar and a tread which is exchangeably fixed to this bar and which is likewise horseshoe-shaped. The advantage of such composite horseshoes is that the tread can be replaced in a simple manner, without the carrier iron, which is usually nailed to the hoof, must be replaced. A major disadvantage of both the horseshoes known for centuries as well as the above composite horseshoes is that the horse's beam (hoofbeam) has little contact with the ground when walking, as the hoof protection (eg horseshoes) distances the beam from the ground. This has drastic consequences for the horse as the natural hoof mechanism is disturbed. When the untreated hoof is touched to the ground, the front edge of the hornbone is pulled back down and the bales are pushed apart so that the beam also makes contact gets to the ground and thereby can pass on the lying in the dermis nerve endings information about the soil condition. In addition, by the ground contact of the beam, a pumping effect is triggered, which ensures the good circulation of the hoof and at high load has a decisive share of the total blood flow of the legs. Therefore, hooves also speak of the horse's four "extra hearts." The pumping effect stimulates the metabolism, relieves the heart, and supplies blood to the organs, greatly improving the horse's overall performance.

If the jet is permanently distanced from the ground and thus permanently without or with insufficient stimulation, the pump effect remains wholly or at least partially. This causes the metabolism to go back and the heart to maintain the complete circulation. This is a heavy burden for the horse's heart in the long term. In addition, the organs are only insufficiently supplied with blood and thus with nutrients. Furthermore, the inadequate pump effect leads to back problems and fat legs in the horse. In addition, the horn growth stunted.

 Another problem with an insufficient pump effect of the beam is a frequently observed navicular and coffin bone drop, which can lead to serious damage to the musculoskeletal system of the animal. Furthermore, in the horses, which wear a conventional hoof protection, often erroneous to observe. Also, in horses wearing such Hufschutzbeschläge,

Hoof roll diseases (podotrochlosis). The hoof roll is used to deflect the deep flexor tendon that runs down along the ankle, forward, where it attaches to the coffin bone. The coccyx disease can be described as an onset of wear, whereby the proportions of the hoof roll (deep flexor tendon, bursa and bladder) can be affected differently. The symptoms are swingless gait, slight upswing of the forelimb (to reduce landing on the hind part of the hoof) and / or lameness. Many horses with hoof roll disease also have abnormal hoof form. If the costumes are too low or too low, the pressure exerted by the deep flexor tendon on the navicular bone is greater than in the case of slightly higher national costumes. On the other hand, hooves with very upright heels and stunted rays are sometimes the result of a longer history of hoof roll disease, with this hoof shape reducing the hoof mechanism. so that the landing is accompanied by an abrupt loading of the navicular area, which often also contributes to the painfulness.

 Furthermore, in horses with the o. G. Horseshoes chronic laminitis and osteoarthritis observed.

To the o. G. To minimize problems, DE 20 2008 012 227.9 describes a hoof protection with straps and the tread iron attached tread, which is also designed horseshoe-shaped. The two legs of the horseshoe-shaped tread are connected to each other via a flexible bridge, on which a plate for contacting the beam of the horse is arranged. This is to bridge the distance between the hoof beam and the ground when the horse appears. This in turn activates the pumping effect of the jet and minimizes the above-mentioned problems. The disadvantage of the hoof protection mentioned in this publication is, in particular, that it can not be adapted to the different circumstances (eg anatomy, hoof sizes, etc.), since the shape of the tread, in particular in the region of the hoof jet, is predetermined. It is rather a matter of luck with this hoof protection, whether this is suitable for the anatomical conditions of the respective horse or not.

 Another problem of said hoof protection is that you can work exclusively with a tread. For example, it is not possible to use and retrofit a simple horseshoe that does not carry a tread that is quite costly.

The present invention has for its object to overcome the above-mentioned disadvantages of the hoof protection devices of the prior art. One of the objects of the invention is to provide a hoof protection with which optimum contacting of the hoof jet is possible with different anatomical conditions and which is also simple and inexpensive, even using conventional carrier devices (in particular horseshoes) of all sizes can be. This object is achieved according to the invention by a hoof protection system of the type mentioned above, which can be fastened to the end regions of the connection iron and bridged beam segment, the two connectable with the respective Endberei- surfaces of the connecting iron connecting leg and a disposed between the connecting legs beam portion for contacting the beam of a Horse includes.

This novel hoof protection system brings enormous advantages over the above-described hoof fittings of the prior art. Due to the fact that the connecting iron and the beam segment in the unassembled state are independently formed parts, the beam segment can be optimally adapted to different sizes of connecting iron and to different anatomical conditions in the horse. In addition, it is possible to provide simple horseshoe without tread with said beam segment, so as to a simple and inexpensive hoof protection system with the o. G. To get advantages in terms of contacting the beam.

In a particularly preferred embodiment of the hoof protection system according to the invention, the connecting legs of the jet segment each have a running in the longitudinal direction of the connecting leg elongated recess, which recesses are formed across or not by cross.

By means of these elongate recesses, a particularly advantageous adaptation of the jet segment to the connecting iron is possible, for example by connecting means (eg, clamping sleeves, see below) through the recesses and already easily attached to the hoof (eg, with continuously formed recesses) by inserting into holes provided for this purpose) so that the beam segment can still be moved to adjust it before it is finally firmly connected to the connecting iron (eg by tightening the clamping sleeves, see below).

Preferably, the connecting legs of the jet segment each have a length which is suitable for connecting the legs of horseshoes of any size. With Advantageously, the lengths of the connecting legs of the jet segment are dimensioned so that they protrude beyond the respective legs of the connecting iron after the connection with the connecting iron. The connecting legs then only have to be cut to length so that their ends terminate with the outer edges of the legs of the connecting rod.

In a preferred embodiment, in which a tread can be dispensed with, the elongate recesses are formed in a sweeping manner and preferably have a stepped edge, wherein the fastening of the jet segment in this embodiment preferably takes place on the connecting iron via at least two connecting pins, in particular clamping sleeves, which engage in engage the respective elongated recesses and are connected at one end with a respective end plate, which end plates in the assembled state rest on the respectively associated stepped edge of the recesses so that they are aligned with the hoof surface of the connecting leg of the jet segment. By this fastening technique is prevented when attaching the jet segment on the support surface of the connecting iron (wing = hoof facing side) raised areas arise that could affect the hoof. This is achieved in particular by the advantageous design of the jet segment with recesses with stepped edge in interaction with the fastening means in the form of clamping sleeves, which are provided at one end with a final bleaching.

In a preferred embodiment of the inventive hoof protection system, a beam contacting element is arranged on the beam section of the beam segment, which is preferably adaptable in its position and / or shape to the anatomical conditions, wherein preferably also the height of the beam contacting element, in particular by shims, is adjustable , In this way, the hoof protection system can be adapted to a wide variety of anatomical conditions. The, the beam of the horse contacting Strahlkontaktierungselement is usually made of soft plastic. It is advantageous that the beam contacting element can be detachably connected to the beam segment in order to - according to anatomical conditions - beam contacting element use different Shorehärten. An advantageous Strahlkontaktierangselement has proven to have a Shore hardness of about 80 °. Also, to accommodate different anatomical conditions, shims may be placed between the beam segment and the beam-contacting element to regulate the height of the beam-contacting element. The shape of the Strahlkontaktierangselement may be different in order to adapt to the respective anatomical conditions.

In the beam segment described above, which is mounted on the support surface of the connecting iron, polycarbonate is advantageously used for the production. This material has proven to be particularly suitable in terms of stability and Verwindbarkeit.

Advantageously, a plurality of recesses for the passage of fastening means are provided at the beam portion of the jet segment, which are preferably arranged in pairs and / or offset from each other. This serves the adaptability of Strahlkontaktierangselement or shims to the different anatomical conditions. Thus, it is thereby possible to position the Strahlkontaktierangselement at different points of the beam portion of the jet segment.

Preferably, the jet section has a rounded tip projecting from the connecting legs, which in the assembled state points in the direction of the closed front side of the connecting iron. This rounded tip prevents injuries when the horse is riding and contributes to a high wearing comfort. In a particularly preferred embodiment of the hoof protection system according to the invention, the jet section is rounded on the bottom side in a front region pointing in the mounted state in the direction of the closed front side of the connection iron, in particular in the region of the rounded tip. This rounding (see also figure description) has enormous advantages when walking and also galloping the horse. It brings particular advantages in Hufrollenbereich (eg beam leg, coffin bone) of the horse. Under the hoof roll area the inner area of the hoof is called. This is independent of the outer area (outer Horn capsule). By said rounding of the front portion of the jet portion of the jet segment of the hoof protection system according to the invention, movement of the hoop roll area is possible independently of the horn capsule. By this rounding in conjunction with the inherent flexibility of the beam segment, a pivoting of the beam section of the beam segment about its transverse axis is possible when walking or galloping the horse. This means that the beam segment is pivoted downwards in the front area along the radius of the rounding towards bottom in the footing. As a result, the beam contacting element can "move along" with the inner joints of the hoof roller area when walking or galloping the horse, regardless of the outer area of the hoof This beam support, which is relatively independent of the position of the beam member, may be used to transmit forces from the rear portion of the hoof and the heels to the beam and the underlying beam pad, depending on the selected height of the beam segment As a result, the improved blood flow can also positively influence the formation of horns, while galloping can lead to a swiveling of up to 25 °.

For the reasons set forth above, the beam portion is pivotally formed, wherein preferably the front portion of the beam portion, in particular the rounded tip from a zero position, in which the entire hoof surface of the jet segment is positioned parallel to the support surface of the connecting iron, when walking or running of the horse to Max. about 30 °, preferably about 10 ° to 25 ° in the direction of the bottom is pivotable. Such pivoting is in particular by the appropriate choice of the material of the jet segment (preferably polycarbonate), its thickness

(Preferably about 1 - 3 mm) and the width of the connecting legs (preferably about 30 mm) reached.

The beam segment, already mentioned above, which is used to manufacture a hoof protection system according to the invention on the support surface of any conventional one

Horseshoe can be arranged is narrow, in particular formed with a thickness of 1 mm to 3 mm and on the hoof facing side of the connecting iron arranged on the ground-facing side (in the assembled state) of the beam portion, preferably integrally connected to the beam segment height compensation is arranged, which preferably has the same thickness as the connecting iron. As a result, a support of the inner hoof area is achieved. Said height compensation is preferably integrally formed on the beam segment. The height compensation is essentially limited to the beam section of the beam segment. If the height compensation also extend to the connecting legs, in particular in the region of the elongated recesses, an adjustment of the jet segment by moving connecting means in the elongated recesses would be difficult. Therefore, the height compensation is essentially limited to the beam section. It is preferred that said height compensation in the front region has a rounding already described above. This rounding brings along the advantages mentioned above (pivoting or rolling along the radius of the rounding).

In a further preferred embodiment of the hoof protection system according to the invention the beam segment is arranged as part of a tread on the side facing away from the hoof of the connecting iron, wherein on the hoof facing side of the beam portion of the beam segment preferably a Strahlkontaktierungselement is arranged, the height of which is preferably adaptable to the anatomical conditions is. Such a beam segment is preferably made of a flexible plastic, such as thermoplastic polyurethane (TPU). Such a beam segment, which is connected to a beam contacting element, is installed, for example, in contact with the beam. The beam contacting element can be provided with a basic setting of 6 mm internal height (corresponds approximately to the thickness of a conventional horseshoe), so that it forms a straight line with the connecting iron, the so-called zero position (here the hoof facing surface of the Strahlkontaktierungselements with the supporting surface of the horseshoe). At a greater distance from the beam to Strahlkontak- tierungselement can be modeled with a kneading plastic mass of the compensation at Strahlkontaktierungselement prior to assembly. The beam segment with the connected beam contacting element and the modeled plastic mask se can then be screwed to the connecting iron. When the hoof is grounded, a negative impression can be taken. The plastic compound usually cures in a few minutes and then adheres to the beam contacting element. As a result, depending on the shape of the beam, an ideal load absorption at the beam and the following joints can be achieved. Due to the flexible properties of said jet segment, which may be part of the tread, the navicular bone and the coffin bone are advantageously supported in almost any position in the movement sequence. For example, X-rays showed a displacement of the coffin bone up to 15 ° during normal walking of a horse. The side of the jet segment facing the bottom advantageously also has the abovementioned rounding in the front region.

The angle which the longitudinal axes of the connecting legs or the longitudinal axes of the elongate recesses in the connecting legs of the jet segment enclose with one another is preferably approximately 120 ° to 170 °, in particular approximately 130 ° to 150 °. This makes it possible to combine the jet segment with conventional horseshoes of all sizes.

The present invention further relates to a hoof fitting for use as a beam segment for assembling a hoof protection system according to the invention, comprising two connecting legs connectable to the respective legs of a horseshoe-shaped connecting rod and a beam portion arranged between the connecting legs for contacting the beam of a horse, the length of the connecting legs being at the distance is adaptable between the two legs of the connecting iron. This adaptation is usually possible by simply cutting the projecting connecting leg sections of the jet segment. At this point, it should be emphasized that the material of the connecting iron in addition to metal (eg iron, aluminum) can also be plastic. The present invention further relates to a kit comprising a carrier iron and a hoof fitting element according to the invention. Further features of the invention will become apparent from the following description of preferred embodiments of the invention in conjunction with the drawings and the dependent claims. In this case, the individual features can be implemented individually or in combination with each other. In the drawings show:

A plan view of an inventive beam segment;

Fig. 2 is a front view of the jet segment of Fig. 1;

Fig. 3 is a side view of the jet segment of Fig. 1; a plan view of an inventive hoof protection system using the jet segment of Fig. 1; a longitudinal section through the hoof protection system of Fig. 4 in the region of the clamping sleeves:

Fig. 6a-6c: a clamping sleeve used in the hoof protection system of Figure 4;

7 shows a bottom view of a further embodiment of a hoof protection system according to the invention;

Fig. 8 is a plan view (hoofside) of the hoof protection system of Fig. 7;

9 shows a perspective view of the hoof protection system of FIG. 7 in the fully assembled state (bottom-side view);

10 is a perspective view of the hoof protection device of FIG. 9. FIG

(hoofside view). 1 shows a plan view of a beam segment 1 according to the invention, which comprises two connection legs 2a, 2b which can be connected to the respective end regions of a horseshoe and a beam section 3 arranged between the connection legs 2a, 2b for contacting the beam of a horse. The connecting legs 2a and 2b each have parallel to their longitudinal axes extending elongated cross-recesses 4a, 4b. The recesses 4a and 4b have on their longitudinal sides in each case a stepped edge 5, which has a smaller thickness than the remaining regions of the jet segment 1. In the area of the stepped edges 5, the beam segment 1 has a thickness of only 2 mm. Incidentally, the connecting legs have a thickness of about 3 mm. The stepped edges 5 play an important role in securing the jet segment 1 to a horseshoe (see below). The connecting legs 2a and 2b have a width of about 30 mm. The beam segment 1 is made of polycarbonate.

 In the region of the beam section 3, which contacts the beam of a hoof in the monited state, six cross-cut recesses 6 are introduced. The

Recesses 6 are arranged in pairs so that the first two pairs next to each other and the pair in the region of the rounded tip 7 of the jet section 3 are behind each other. The recesses 6 are used for fastening a Strahlkontak- tierungselements. If, in the mounted state, the beam section 3 does not yet contact the beam, a beam contacting element is mounted on the hoof side 8 of the beam section 3. Depending on the anatomical conditions also shims between the beam section 3 and a Strahlkontaktierungselernent not shown here can be mounted to achieve a contacting of the hoof beam. Due to the staggered arrangement of the recesses 6, a beam contact element or shims can be arranged at different positions on the beam section 3. This allows different anatomical conditions to be taken into account on the hoof. The rounded tip 7 rises from the connecting legs 2a, 2b and points in the mounted state in the direction of the closed front of the horseshoe.

Figure 2 shows a front view of the jet segment 1. The hoof surface 8 is formed flat throughout. In the area of the beam section 3, in the present embodiment no beam contacting element mounted. To the bottom surface 9, so that side of the jet segment 1, which faces the ground in the mounted state, a height compensation 10 is formed. The height compensation 10 is integrally formed on the beam segment 1. This height compensation 10 has a thickness of about 6 mm (measured from the bottom surface 9 to the base 1 1 of the height compensation 10), which corresponds to the thickness of a conventional horseshoe. The base 1 1 of the height adjustment 10 is aligned in the mounted state so with the bottom surface of the horseshoe. In the height compensation 10, the recesses 6 are introduced, which serve the attachment of a Strahlkontaktierungselements or the attachment of compensation discs. The attachment of Strahlkontaktierungselement or shims takes place in the present embodiment by self-locking hard plastic bolts.

3 shows a side view of the jet segment 1. In this illustration, it can be clearly seen that the jet section 3 is rounded on the bottom side in the region of the rounded tip 7 (rounded section 13). The rounded portion 13 is also part of the height compensation 10, wherein the rounded portion 13 on the bottom side merges into the base 1 1 of the height adjustment 10. The rounded region 13 is extremely advantageous when walking or running a horse. Due to the rounded region 13, when the horse is caught in the area of the rounded point 7, this area is pivoted by rolling towards the ground. Thus, the beam section 3 pivots in the front region, starting from a zero position, in which the hoof surface 8 of the jet section 3 is substantially parallel to the ground, when walking the horse by about 15 ° towards the ground (see arrow). Thus, a constant ontaktierung the Hufrollenbereich of the hoof during Auffußen possible by the beam section 3 "can go along" with the Hufrollenbereich of the horse The Hufrollenbereich is independent of the Hom capsule and pivots when the horse is squeezed by the choice of material, the width and The thickness of the connecting legs as well as the rounded area 13 allow a perfect pivoting of the beam section 3 when the horse is sitting on the ground. During normal walking, the beam section pivots about 15 °, whereby a greater pivoting of up to 30 ° is possible during galloping. It should also be emphasized that Pivoting by 45 ° and more is excluded, thereby avoiding injuries to the hoof, especially in the beam area.

Figure 4 shows a plan view of the support surface of a Hufschutz- system 20 according to the invention with a connecting iron 14 and the beam segment 1, which is attached to the connecting iron 14. When connecting iron 14 is a conventional horseshoe with horseshoe shape, which is made of iron. The beam segment 1 is fixed by means of clamping sleeves 15 on the connecting iron 14. Such a clamping sleeve 15 is shown in Figures 6a to 6c. As shown in the mentioned figures, the clamping sleeves 15 carry at one end in each case a sheet metal plate 16, which is welded to the clamping sleeve 15. Such a sheet metal plate 16 has a width which corresponds to the width of a recesses 4a including the two stepped edges 5. In addition, a sheet metal plate 16 has a thickness of 1 mm. In the assembled state, the sheet metal plates 16 are in the recesses 4a and 4b, that they rest on the stepped edges 5, so that their tops are aligned with the hoof surface 8 of the jet segment 1. This creates a flat surface and impaired wearing comfort by raised areas are avoided. When mounting the jet segment 1 on the connecting iron is generally proceeded so that first the clamping sleeves 15 are guided with their free end through the recesses 4a and 4b of the connecting legs 2a and 2b and easily inserted in the clamping sleeves 15 predetermined recesses in the connecting iron 14. In this state, the position of the jet segment 1 can be adjusted by displacement along the recesses 4a and 4b, since in this state, the clamping sleeves are not yet introduced in their entire length in the connecting iron 14. If the desired position is reached, the beam segment 1 is finally fixed by tightening the clamping sleeves, which is usually hit with a hammer on the metal plate 16. After fixation of the jet segment 1 on the connecting iron 14, the respective protruding portion 17 (shown here in dashed lines) is cut along the outer sides 18 of the horseshoe legs, so that the end faces of the connecting legs 2a and 2b then terminate substantially flush with the outer sides 18 of the horseshoe legs. FIG. 5 shows a cross section through the hoof protection system 20 of FIG. 4 in the region of the clamping sleeves 15, the protruding sections 17 having already been removed here. In this illustration, it is easy to see that the sheet metal plates 16 form a flat surface on the clamping sleeves 15 with the hoof face 8 of the jet segment 1. by these sheet metal plates 16 rest on the stepped edges 5 of the recesses 4a and 4b. Due to the advantageous design of the sheet metal plates with a thickness of about 1 mm they play optimally with the 2 mm thick stepped edges 5 together. With a thickness of the sheet metal plates of 1 mm and a thickness of the stepped edges 5 of 2 mm results in a total thickness of 3 mm, which corresponds to the thickness of the connecting legs 2a and 2b. The clamping sleeves 15 have a length of about 6 mm. This length corresponds to the thickness of the connecting iron 14, so that the clamping sleeves 15 do not protrude from the connecting iron 14 in the mounted state, whereby a pressing out of the clamping sleeves 15 is avoided. The beam segment 1 is ideal for mounting on all known horseshoe shapes and sizes. With the help of the jet segment 1, an assembly of an extremely simple and inexpensive hoof protection device is possible. In particular, the adaptability of the jet segment 1 to the most varied shapes and sizes of horseshoes makes it so valuable.

FIG. 7 shows a plan view of the bottom side of a further embodiment of a hoof protection system 120 according to the invention with a further embodiment of a jet segment 101 according to the invention. The jet segment 101 also has two connecting legs 102a and 102b and a jet section 103 arranged between the connecting legs 102a and 102b for contacting the jet Horse up. The connecting legs 102a and 102b of the jet segment 101 have longitudinal recesses 104a and 104b running in the longitudinal direction of the connecting legs, which are not formed in a sweeping manner. The beam segment 101 has a thickness of about 1 cm. In the region of the non-penetrating recesses 104a and 104b, the thickness of the jet segment 101 is approximately 0.5 cm. In contrast to the above-described hoof protection system 20, in which the beam segment 1 is mounted on the support surface (hoof surface) of the carrier iron 14, in the case of the hoof protection system 120, the jet segment 101 is arranged on the bottom surface (the side facing the bottom) of the connecting iron 1 14 and forms in this embodiment, the rear portion of a total of four segments tread 105. The I .aufbelag is composed of the beam segment 101 and three others replaceable tread segments 105a, 105b and 105c together. In the beam section 103, six recesses 106 are provided for carrying out fastening means for fastening a beam contacting element. In the present embodiment, a beam contacting element 121 is arranged on the hoof surface 108 of the beam segment 101 in the region of the beam section 103. The beam contacting element 121 is fastened to the beam segment 101 via three hard plastic bolts 125 (see FIG. 10). Due to the paired arrangement of the recesses 106 in the beam section 103, it is possible to adapt the position of the beam contacting element 121 on the beam section 103 to different anatomical conditions. The jet section 103 has a rounded tip 107 emerging from the connecting legs 102a and 102b, which points in the direction of the closed front side of the connecting iron 14. The beam section 103 is provided on the bottom side in the region of the rounded tip 107 with a rounding 13. By this rounded portion 1 13 is a pivoting (rolling) of the beam portion 103 about its transverse axis (towards the ground) when walking or running of the horse possible.

The beam segment 101 is arranged on the connecting iron 1 14 via screws 1 15. The heads of the screws 1 15 are located in the recesses 104a and 104b and do not protrude beyond this. This prevents pressure on the screw heads when walking or running the horse. In the present representation, the portions 1 17 of the connecting legs 102a and 102b, which protrude beyond the two legs of the connecting iron 114, not yet cut to length. However, this is usually carried out by the connecting legs 102a and 102b are cut to length in the region of the outer sides 1 18 of the legs of the connecting iron 1 14. FIG. 8 shows the system 120 on the hoof side, ie that here the support surface of the connecting iron 114, which has contact with the hoof. is shown.

Figure 9 shows a perspective view of the device 120 of Figure 7, wherein the bottom side is shown here. In this illustration, the protruding portions of the connecting legs 102a and 102b have already been cut to length so that the connecting legs are flush with the outer sides 118 of the connecting iron 14. It can also be clearly seen in this illustration that the heads of the screws 115 are positioned in the recesses 104a and 104b and do not project beyond the bottom surface 109 of the jet segment 101. Further, in this illustration, a profiling in the tread segments 105a and 105c is located.

FIG. 10 shows a perspective view of the hoof protection system 120, the support surface of the connection iron 1 14 or the hoof surface 108 of the jet segment 101, which faces the hoof in the installed state, being shown here. In order to ensure contact of the jet of the horse, the beam contacting element 121 is arranged in the region of the beam section 103, wherein a shim 122 is arranged between the beam section 103 and the beam contacting element 121. The shim 122 serves to increase the beam contacting element 121 to guarantee contact of the beam by the beam contacting element 121 in a horse. Such shims 122 are used in horses whose beam is higher than usual and therefore contact with a Strahlkontaktierungselement conventional height (usually 6 mm, which corresponds to the thickness of a conventional horseshoe) is not possible. In the present embodiment, the hoof surface 123 of the beam contacting element 121 is located on a plane which is parallel and above the plane on which the support surface of the connecting iron 1 14 is located. The beam contacting element 121 and the shim 122 are secured to the beam segment 101 by means of self-locking hard plastic bolts 125. The shim 122 is made of hard synthetic material, the beam contacting element being made of a rather soft plastic (eg Shore hardness of 80 °). The jet segment 101 is made of thermoplastic polyurethane (TPU). In this illustration, the rounded portion 1 13 can be seen. By means of this rounded region 13, pivoting of the jet section 103 together with the beam contacting element 121 and shim plate 122 in the direction of the ground (see arrow) is possible when the horse is walking or running. As a result, the beam contacting element 121 adapts to the movements of the hoop roller area during the footing of the horse.

Furthermore, two elevators 126 of the horseshoe 1 14 can be seen in this illustration, which serve to stabilize the entire apparatus 120.

Claims

claims

Hufschutzsystem (20, 120) for horses or the like ungulates with a fastened to the hoof, in particular horseshoe-shaped connecting iron (14, 1 14) and one attachable to the two end regions of the connecting iron and these bridgeable beam segment (1, 101), which two with the respective Connectable connecting leg (2a, 2b, 102a, 102b) and an arranged between the connecting legs beam portion (3, 103) for contacting the beam of a horse or the like ungulate comprises.

Hoof protection system (20, 120) according to claim 1, characterized in that the connecting limbs (2a, 2b; 102a, 102b) of the jet segment (1, 101) each have an elongated recess (4a, 4b; 104a, 104b) extending in the longitudinal direction of the connecting limb. have, which are formed through or not by cross.

Hoof protection system (20) according to claim 2, characterized in that the elongated recesses (4a, 4b) are formed by cross-over and preferably a stepped edge (5), wherein the attachment of the jet segment (1) on the connecting iron (14) preferably over at least two Connecting pins, in particular clamping sleeves (15) takes place, which engage in the respective elongated recesses (4a, 4b) and are connected at one end to a respective end plate (16), which end plates in the assembled state on the respective associated stepped edge (5) of the recesses (4a, 4b) lie in alignment with the hoof surface (8) of the connecting legs (2a, 2b). Hoof protection system (20, 120) according to any one of the preceding claims, characterized in that on the beam section (3, 103) of the jet segment (1, 101) hoof contacting a Strahlkontaktierungselement (121) is arranged, which preferably in its position and / or in his Shape is adaptable to the anatomical conditions, wherein preferably also the height of the beam contacting taktierungselement, in particular by shims (122) is adjustable.

Hoof protection system (20, 120) according to one of the preceding claims, characterized in that at the beam section (3, 103) a plurality of recesses (6,

106) are provided for the implementation of fastening means, which are preferably arranged in pairs and / or offset from one another.

Hoof protection system (20, 120) according to one of the preceding claims, characterized in that the beam section (3, 103) has a rounded tip (7, 107) emerging from the connecting limbs (2a, 2b, 102a, 102b), which in the mounted state towards the closed front of the connecting iron (14, 1 14) points.

Hoof protection system (20, 120) according to one of the preceding claims, in particular according to claim 6, characterized in that the beam section (3, 103) on the bottom side in a front, in the mounted state in the direction of the closed front of the connecting iron (14, 1 14) facing Region (13, 1 13), in particular in the region of the rounded tip 7, is rounded.

Hoof protection system (20, 120) according to one of the preceding claims, in particular according to one of claims 6 or 7, characterized in that the beam section (3, 103) is pivotable, wherein preferably the front region of the beam section, in particular the rounded tip (7 .

107) from a zero position, in which the entire hoof surface (8, 108) of the blasting section (3, 103) is positioned parallel to the supporting surface of the connecting rod (14, 14). when walking or running the horse by max. about 30 °, preferably about 10 - 25 ° in the direction of the bottom is pivotable.

9. hoof protection system (20) according to any one of the preceding claims, character- ized in that the beam segment (1) is formed with a thickness of about 1 mm to 3 mm and in the assembled state on the side facing the hoof (wing) of Connection iron (14) is arranged, wherein on the ground-facing side (9) of the beam portion (3), preferably integrally connected to the beam segment (1) height compensation (10) is arranged, which is preferably the same thickness as the connecting iron (14).

10. hoof protection system (120) according to any one of the preceding claims 1 to 8, characterized in that the beam segment (101) in the mounted state as part of a tread (105) on the side remote from the hoof of the connecting iron (1 14) is arranged, wherein on the side facing the hoof 108 of the beam segment (101) in the region of the beam portion (103) is preferably a Strahlkontaktierungselement (121) is arranged, the height of which is preferably adaptable to the anatomical conditions.

1 1. Hufschutzsystem (20, 120) according to any one of the preceding claims, characterized in that the angle which the longitudinal axes of the connecting legs (2a, 2b, 102a, 102b) and the longitudinal axes of the elongate recesses (4a, 4b, 104a, 104b) with each other, about 110 ° - 170 °, preferably about 130 ° - 150 °.

12. hoof fitting element (1, 101) for use as a beam segment for assembling a hoof protection system (20, 120) according to one of claims 1 to 1 1, comprising two connectable with the respective leg of a horseshoe-shaped connection iron (14, 114) connecting leg (2a , 2b; 102a, 102b) and a beam section (3, 103) arranged between the connecting arms for contacting the beam of a horse, the length of the route connecting leg is adaptable to the distance between the two legs of the connecting iron.

A kit comprising a carrier iron and a horseshoe element according to claim 12 for mounting a hoof fitting system according to any one of claims 1 to 11.