WO2003089366A1 - Saddle and method for adapting a saddle - Google Patents

Abstract

The invention relates to a saddle, whose special construction aids the rider to train and correct the ridden horse and maintain it in good health by means an orthopaedic action, in addition to a method for adapting a saddle with an action of this type. To this end, the saddle is not adapted to the horse, but is constructed from a passive-action element and an active element in such a way that the musculature of the horse is developed in a desired form.

Description

 Patent application (PCT) "Riding Saddle and Method for Adapting a Riding Saddle"

description

The invention relates to a riding saddle, the special construction of which enables the rider to receive orthopedic help for training, maintaining health and correcting the ridden horse, as well as a method for adapting a correspondingly acting riding saddle. The saddle is not adapted to the horse, but rather constructed from a passive and an active element in such a way that the muscles of the horse develop in the desired shape.

The present invention is based on the problems that arise from the natural asymmetry of a horse or riding horse. This so-called "naturally skewed" corresponds to the general asymmetry in vertebrates, because the preference of right or left is a common design principle in vertebrates. Regardless of the theory on which these natural symmetry breaks are based, they become a problem as soon as the naturally crooked horse has to carry a rider and perform certain exercises that become more difficult the more asymmetries occur, including the asymmetry of the rider can become a problem. This natural crookedness can not only be hereditary or birth-related, but can also be acquired through lack of movement or mistakes in rearing and injuries later in life. Even a permanent protective posture or misunderstood gymnastics of the horse under the rider can lead to crookedness. Regardless of the cause, this crookedness is a basic problem when training a riding horse.

The original meaning and purpose of the classic training of a riding horse takes into account the correction of this skew. A distinction is made according to the six levels of the training scale, namely tact, letting go, leaning, Momentum, straightening, assembly. These do not serve an end in themselves, but to keep the horse healthy under the rider's weight, because a crooked - i.e. not straightened - horse will neither show itself in tact, let go, lively, straight or even assembled under its rider. These basics of cavalry are highly interdependent and cannot be viewed or trained separately.

In times of intensive use as transport or war equipment, the military and stud farms had enough instructors for horses who mounted horses in the sense of this classic riding training, so that such correction problems occurred less frequently. In today's times, however, the horse is used almost exclusively for leisure purposes, so that in many cases the training is left to the inexperienced rider himself and the horse's health is severely affected. Accordingly, there are often horses that struggle with irreparable back problems at a young age, as well as the resulting secondary problems that arise on the limbs. The most common root cause of all these problems up to serious postural problems, which in turn cause organic problems due to vertebral blockages, lies in the skewness of the horse, which was not corrected accordingly in the course of riding horse training.

In the following, the biomechanical problem of the horse's body is to be explained with the aid of drawings in order to explain the causes of the skewing and its consequences for the keeping apparatus and to make the solution of the problem according to the invention understandable therefrom.

1A shows the body parts of the head, neck, chest, loin, sacral bone and tail arranged along the spine.

The forehand of the horse shown in FIG. 1B consists of the shoulder blade, upper arm, spoke, tube, fetlock and hoof.

The hindquarters of the horse shown in FIG. 1C consist of the pelvis, thigh, shin, tube, fetlock and hoof. All four hooves together form the rectangular support surface and the connection of the horse's trunk to the ground.

In Figure 1 D, the two forelimbs of the forehand are shown from the front. It can be seen that these are connected via a crossed loop to form a "H-shape" in which the horse's chest is movably suspended.

Figure 1 DD shows this chest suspension in the movement of the horse when the forelimbs are raised.

Figure 1 E shows the hind quarters from behind. The hind limbs form an "A-shape", the hindquarters on the pelvis being articulated to the spine via the sacral joint as the tip of the imaginary "A-shape".

Figure 1 EE shows the shift of the "A-shape" when the hind limbs are raised.

FIGS. 1 F and 1 FF show how the vertebral group can move (Fig. 1 F) and while standing (Fig . 1 FF) is kept in a stable equilibrium.

In this skeleton construction, the spine forms the pressure-bearing abutment. The spinous processes and the chest serve as starting points for ligaments and muscles. This complex system is able to balance the gravity from above while standing and moving. This upper and lower beam system is able to work with weights higher than the horse's own weight, e.g. B. in pregnant mares with the additional weight of the foal. Therefore, the construction can also cope with an additional rider weight.

The lateral muscle groups, which prevent the torso from deflecting to the side, are only designed for the forces that arise in the movement of the horse and for a permanent change of tension and relaxation. but to compensate for lateral asymmetries, which are reinforced by additional rider weight. Due to the crookedness of the horse, these lateral muscles are not symmetrical.

If a crooked horse is now loaded by the rider's weight and the saddle in the area of the long back muscle, the weaker muscle-shortened side of the horse automatically yields. For a horse with a more pronounced right half of the body (right-handed), this results in the following circumstance, which will be explained with the aid of further figures:

FIG. 2A shows a rider in equilibrium over a symmetrically designed horse body, as this would be the optimal state.

FIG. 2B, which shows a top view of the horse's back, shows how the left back muscle, as the shortened and therefore weaker muscle, yields more under the rider's weight than the right one. Thus the saddle tilts - even without the rider sitting wrong - into the weaker back half, namely to the left. This shifts the rider's center of gravity to the left half of the horse's body. The desired centric force transmission over the spine is no longer taking place. Due to the usual fixation of the saddle by its gullet or saddle tree in the area of the longest spinous processes and the belt fastening of the saddle to the horse, this asymmetrical introduction of force acts as a lateral force from the right on the vertical spinous processes of the thoracic spine. This lateral, unwanted force continues as a left-turning torsional load in the body of the horse.

FIG. 2C shows the consequence of this torsional load for the rider's weight above the center of gravity: the body is deflected to the right. The area of the spine behind the forehand accordingly forms a left arch, with the shoulder shifting. The neck in turn forms a right arc.

In order to restore a balance of power in this state, the right side muscle group of the horse must now work permanently. As already mentioned, the muscle groups are only for changing loads intended. Thus, this automatic attempt to restore the balance of forces leads to an overload of these lateral muscles. As a further consequence, muscle groups that are only intended for locomotion have to take on additional stabilization tasks. The shoulder, back and croup muscles of the horse are particularly affected by this change in functionality. The also recognizable shifting of the left shoulder backwards leads to the fact that it is pressed against the saddle and there is an additional pressure load.

FIG. 2D shows a side view of the spine of the oblique load described above. It can be seen that the base of the cervical spine lowers relative to the desired posture shown in FIG. 2E, while the spine rises in the lumbar region. The point of support of the rear limbs is also higher due to the steepness of the pelvis. This incorrect posture is colloquially called "the horse goes on the forehand". In fact, in this situation, the spine is already bent or bent in three dimensions and the spine pressure rod must be permanently stabilized by the holding muscles and movement muscles in order to prevent further lateral deflection. As a result, the rider sits downhill emotionally, while the horse holds on to the back muscles and "does not let the rider sit". In addition, the flexing of the lumbar muscles means that no bending in this area is possible. This intended main bending point in the lumbar region rather shifts forward into the expiring region of the withers and concentrates on the 12th to 13th vertebrae. This does not result in the desired bend, but a kink in the spine under the saddle area. The horse runs, so to speak, "over the shoulder". In this state, any spinal canal freedom is inevitably too narrow and there are additional pressure peaks under the saddle that can cause pain. Due to these pressure peaks, the horse moves further down in the spine and increases its protective posture. Relaxed motor skills are no longer possible.

There are various consequences from the load on crooked horses. A muscle can only work if a tension phase is followed by a relaxation phase. With constant tension there is no metabolism in the muscles instead and there is an overacidification, ie the muscle tenses or sticks and can no longer work. In addition, the metabolism is permanently burdened by the metabolic products of overacidification. In the medium and long term it happens that in the area of the saddle, i.e. in the area of the long back muscle or trapezius muscle, the blood circulation becomes poorer due to the tense muscles and pressure points with permanent scarring occur. The failure of the musculature and shifting to other muscle groups creates protective postures that result in displaced vertebrae, spinal curvature, crooked shoulders, crooked pelvis and non-functionality. As a result of displaced vertebrae, nerve bruises can develop at the nerve exit points on the spinal canal, which in turn cause problems in the assigned organs and movement muscles. Ultimately, these protective postures overload the limbs in many cases. The most common are hoof roll diseases and tendon damage.

This solves the problem of counteracting the horse's natural or acquired skewness. This is done by targeted gymnastics of the horse using suitable muscle groups. In this context, orthopedic aids have not been presented in a suitable form. In fact, it is also possible to help the horse to compensate for its incorrect posture with a correctly adjusted saddle and the professional training of the rider. However, the known saddles are built to a certain extent for the ideal horse and professional rider. No solution is offered for the estimated remaining 90% of the riders.

The known saddle constructions follow the same principle overall: As before, the saddle construction reduces the horse to the area of the so-called saddle position, which is diagnosed from two dimensions - if necessary using a computer-aided pressure measurement system. So far, however, there is still no approach that sees the horse as a three-dimensional, complex, moving and constantly changing individual, because it is only trying to counteract the described effects in the form of large contact surfaces, which are also designed to be flexible. We also offer saddle pads made from various print absorbent or damping materials. As the closest prior art, WO 98/29331 describes measures which take into account crooked shoulder blades of the horse. However, these measures are limited to purely passive products in the regionally limited area of the saddle layer.

The problem described is solved by the saddle according to the invention and the method according to the invention for adapting such a saddle.

1. The saddle according to the invention

The first solution is to take into account the different tension ratios of the side muscle groups, especially the long back muscle, and relates to the padding of the saddle.

By building up an upholstery tension that corresponds to the respective muscle tension in the left or right side, the lateral forces in the movement system can be eliminated. The materials used to build this tension should be similar to muscle tissue in their mechanical properties, particularly their strength and elasticity. With a symmetrical saddle tree and a variable substructure, the saddle therefore takes on the task of giving the horse active orthopedic help for correcting posture under the rider's weight. The invention is based on the fact that the skewness of the horse can still be corrected, that is to say that the lateral muscle groups can still develop symmetrically under this saddle construction, or a skewness that can no longer be corrected can be compensated for at least to the extent that the horse has no motor disadvantages under the rider's weight towards a straightened horse.

The second approach is to adapt the rigid part of the saddle tree. According to the invention, a distinction is made between the current and the genetically ideal muscled, posture-corrected condition of the horse. The two-dimensional adaptation of the rigid part of the saddle tree is not chosen according to the current state, but rather according to the ideal state. The aim is therefore not to satisfy an actual state to do, but to create a basis for positive development in the form of posture correction and muscle reshaping.

The third solution is to reduce the main contact area of the saddle in the center. This is done with the help of prestressed plates, which divert the contact pressure of the saddle very broadly like a leaf spring to the rib arch. The "center of the saddle" means the area from approx. 10 cm behind the front edge of the saddle to approx. 10 cm before the rear edge. This derivation of the contact pressure leads to an additional release of the saddle in its front and rear end critical area of the withers spout is supported laterally by the prestressed plates. This gives the horse the opportunity to bulge in the back in this area and not to bend in the spine. This structure prevents the saddle spinal canal, the shoulder end and the rear outlet of the saddle on the horse causes pressure peaks when it bends the thoracic spine downwards.

The structure of the saddle according to the invention will be described below with reference to FIG. 3. The saddle in the seat, the harness and the stirrup construction can correspond to any conventional saddle of different riding styles.

The saddle tree (10) consists of four elements. The seat shell (11) serves as the first element for receiving the belt attachment (12) and the stirrup strap suspension (13). This seat shell can be manufactured as a molded plastic part or laminated from fiber-reinforced plastics. Fastening options (14), for example threaded inserts or bores, are provided in the seat shell for fastening the second element to be arranged underneath, consisting of two interchangeable heels (15). On the side of the seat shell, these interchangeable heels always have the same shape for a positive connection with the seat shell. At the back of the horse, the costumes can be made in various angles and turns. With a seat shell different costumes can be combined to different fits of a horse. The construction is designed so that the traditional costumes on site zester time can be changed to the saddle z. B. to adapt to a new horse. The costumes should preferably be milled from wood to ensure problem-free finishing. High-strength, easily machinable cast plastics can also be used as material for the traditional costumes.

The third element is a spring plate (16) of approximately 2 to 3 mm thick, which is to be arranged under the alternate costumes. This is connected to the seat shell at the markings (17a, 17b) at about 10 cm from the front and rear ends of the saddle below the alternate heels in the spinal canal. Due to the convex cross-section of the alternate heels, this plastic plate creates a leaf spring-like effect from the vertebral canal in the direction of the costal arch of the horse. In the front area of the saddle tree, the plastic plate is made larger so that it extends further down the horse's body. With the English saddle construction in particular, this results in a flexible enlargement of the saddle pads in the area of the stirrup suspension as well as a more extensive support of the horse's trapezius muscle up to its rib box.

As the fourth element, the spring plate is used to screw the panel plate (19) made of elastic plastic, namely preferably PE with a permanently elastic shaping effect that occurs under load, into the vertebral canal of the saddle. The panel plate overhangs the saddle structure in the shoulder area of the horse by approx. 3 to 6 cm and has slots (20). This results in a better three-dimensional cushioning towards the shoulder. In the area of the top iron up to the rear end of the saddle tree, as in the shoulder area, the panel plate is approx. 3 to 8 cm larger than the spring plate above. Slits for softer cushioning can also be installed in this area.

The panel plate is used to hold the saddle cushions (21), which are pulled over them, and thus for further flexible enlargement of the tree support area. The transverse spring effect of the spring plate in the middle part of the saddle is supported and the cushioning in the shoulder inlet and in the loin outlet is carried out. The spring action takes place in the shoulder and lumbar region in the longitudinal direction of the horse. The saddle cushion (21) shown in FIG. 5 with an integrated slit-shaped padding pocket (22) can be made in one or two parts. They consist of a front and a rear insertion pocket (23) for the panel plate (19) on each side, these being largely opposite each other in their opening in order to fix the saddle cushion on the panel plate. The saddle cushions are fully padded with spacer fabrics and covered with a thin plastic plate in the area of the straps in order to distribute the pressure of the belt structure more evenly over the costal arch muscles.

Stamped upholstery panels made of visco-elastic foams and natural latex foam panels are preferably used as the upholstery material. These can be used as full-surface elements in accordance with the panel shape and as partial surfaces for balancing the skew. Sewn-up padding panels made of spacer fabrics can be integrated into the padding insert for better ventilation.

The saddle cushions to be padded serve two different purposes:

On the one hand, they serve to softly cushion the harder parts of the saddle on horseback, as is the case with conventional saddles. They also serve to balance or compensate for skewness. This function can be seen as an active element in combination with the plate construction described below. The system implemented in this way is based on a compensation of the asymmetrical forces applied to the horse's body and the resulting moments. The solution to this balance is to use a one-sided elastic padding element to compensate for the imbalance of the side muscles due to natural or acquired skewness.

This padding causes a permanent one-sided effect on the long back muscle and a shift in the center of gravity of the force application point under the rider's weight.

The construction according to the invention is explained in connection with the advantages over the prior art: Conventional saddle structures sometimes use rigid saddle trees. A disadvantage of this construction is the large rigid tree support, which means that this construction can only be properly adapted to a flat back condition of the horse. If the back line rises under the ridden horse, such a saddle no longer lies flat, but mainly in the middle area. If such a saddle was adjusted according to the back line of the moving horse, the saddle would in turn generate pressure in the front and rear area of the saddle.

This problem is shown in FIG. 6, in which the horse's back line is shown at the bottom, which bends further when standing than when moving, and above it the lower edge of the saddle lying on it. If the saddle is adjusted to the standing horse in such a way that the pressure load is even when standing (Fig. 6a), there is increased pressure load in the middle area when moving the horse (Fig. 6b). If, on the other hand, the saddle is adjusted to the moving horse in such a way that the pressure load is even during movement (Fig. 6d), there is increased pressure load in the shoulder and lumbar region when standing (Fig. 6c).

This problem was recognized a long time ago, whereupon flexible saddle trees were developed, which, however, also have problems. The construction of a steel spring tree, for example, is based on the principle of a leaf spring in the longitudinal axis of the horse. In order to achieve this effect, the saddle trees in the middle area under the rider's weight are only provided with a very small contact area on the horse's back. This also creates an undesirable contact pressure in the front and rear area of the saddle on a crooked horse, which is exacerbated by the almost missing support in the middle area.

In both cases of rigid or flexible saddle trees, these constructions cause higher support bridges on the shoulder blade or in the loin of the horse. These constructions are completely contrary to the newer knowledge of osteopathy, which has the highest load-bearing capacity of the horse's back sees in the area of the vertical spinous processes, ie over a length of 30 to 40 cm in the area of the center of gravity.

The described construction according to the invention solves this problem that undesired pressure points occur in the saddle support area either when standing or during movement.

A basic distinction is made between the wing and the release areas of the saddle. The free areas include the spinal canal - i.e. the ends of the spinous processes - and the shoulder. The spinal canal with its bony structures is particularly sensitive and must be completely free of the fixed structures of the saddle tree over a width of at least 6 to 8 cm. The shoulder, especially the rear upper end of the scapular cartilage, must not touch the saddle tree in any phase of its rotation.

The costal arch provides the most stable wing. The realization of the sport saddles is sometimes only inadequate, because with very long spinous processes of the horse (in the front area up to 20 cm and more) the gullet with the padding does not reach the costal arch. The rigid fixation of the gullet iron creates enormous torques in the area of these spinous processes if the horse is skewed.

According to the invention, the chamber width of the saddle tree is basically to be designed for the shoulder width, the lower curve having to follow the curvature of the ribs and its length depending on the structure of the upholstery on the costal arch. In cases where there is a larger free space between the saddle tree and the horse's back, the space is filled with correspondingly more padding material, so that the horse's back muscles, which are still missing, can develop in this space or the horse can arch its sagging thoracic spine again.

The center of gravity should be above the center of gravity of the horse. As a rule, it lies around the 14th thoracic vertebra or at the deepest point of the back. The maximum length of the saddle tree begins at the rear rotation point of the Shoulder blade to the last thoracic vertebra. The saddle size cannot be determined by the rider's "seat size". These specifications determine the horse, according to which considerable problems can arise with smaller horses with a carrying length of less than 40 cm.

The angulation of the side wings should correspond to the rib angulation. The momentum should follow the horse's back. The front and rear ends of the saddle tree should protrude slightly from the horse's body in the range of 5 to 10 cm.

The structure made of spring and panel panels represents the active part of the construction:

Due to its fixation in the saddle chamber, the spring plate is attached to a length of 30 to 40 cm below the center of gravity. Due to the interchangeable heels, which are convex to the vertebral canal, pre-tensioning is achieved by harnessing the horse and the rider's weight, which acts transversely to the horse's axis. This preload changes depending on the current muscle condition. This means that even when the horse is not in balance, the main support of the saddle remains in the area of the spring plate and the shoulder or lumbar exemption is retained. Furthermore, this leaf spring has a stabilizing effect on the horse in its longitudinal direction in the area of the withers, so that kinking of the spine or displacement of the bending point is avoided in this area. The fixation in the chamber also ensures the release of the spinal canal.

The panel plate strengthens the effect of the spring plate on the one hand through extended spouts to the costal arch and on the other hand forms the elastic spouts towards the shoulder and the loin. The parts of the panel plate protruding in the longitudinal axis form the supporting surface which is partly load-bearing

By preloading the panels under load, a flexible enlargement of the saddle tree support is achieved in the central area of the saddle tree by approximately 100%. In addition, the main edition of the saddle is concentrated in the middle area in which the rider sits in the saddle, whereas the contact pressure is reduced in the shoulder and lumbar area. Due to the high carrying effect of the spring plate and panel plate, this construction allows an overall smaller saddle tree construction in the wing area, which offers the horse greater freedom of movement and brings the rider into closer contact with the horse.

Another outstanding advantage of the construction according to the invention described is that the horse is laterally centered and supported in its thoracic vertebra area of the expiring withers due to the wedge-shaped leaf spring action. As a result, there are no lateral forces and torques in this area, so that the horse can lift itself in the thoracic spine.

This depiction of the removal of undesired force introduction is shown with the aid of FIGS. 7a, 7b, 8a and 8b:

FIG. 7 a shows the body of a straight horse in equilibrium, the common center of gravity S of horse and rider of the body being on the direct connecting line A-C, which can be seen in the projection in FIG. 7 b. The additional rider weight is balanced by the abdominal muscles alone, without stressing the side muscle parts of the horse.

8a shows the body of a leaning horse, the common center of gravity S of horse and rider being deflected out of the direct connecting line A-C, which can be seen in the projection in FIG. 8b.

Due to this deflection, represented as dimension a and dimension b, the abdominal muscles, back muscles and the left and right side trunk muscles are disturbed by the rider's weight so that they have to be used permanently to stabilize the spine instead of their actual function.

As soon as these laterally acting moments are canceled by the padding according to the invention, FIG. 8c, these muscles can work normally again and lift the back including the rider's weight. Another pleasant side effect arises when the horse is inclined to stretch his back down. With conventional saddles, the shoulder and lumbar region are overloaded by the increased saddle support, which the horses find uncomfortable. In this situation, the saddle according to the invention takes over a large part of the contact pressure due to the leaf spring construction, the previously described hollow lying of the saddle being avoided.

The ranges of the spring action of the saddle according to the invention, which is essential to the invention, result from FIG. 4. It shows the plate construction made of alternate costumes (15), spring plate (16) and panel plate (19). This results in a longitudinally elastic spring action in the outer areas of the loin and shoulder of the horse and in the central area of the rider's center of gravity in a transverse elastic spring action.

The structure described in this way can be used as a prefabricated saddle or can also be implemented by converting an existing saddle, the method according to the invention described below being used.

As a further advantageous embodiment, a saddle structure is proposed which, instead of the interchangeable heels, provides a saddle tree construction without interchangeable heels, as a result of which the tree construction becomes flatter so that the rider sits closer to the horse. To compensate, the rigidity and the spring rate of the spring plate and the panel plate must be increased accordingly.

A belt attachment directly to the spring plate is also proposed to be particularly advantageous, as a result of which this is increasingly pressed against the convex costal arch of the horse. This results in a desirable, very wide support on the costal arch.

For a corresponding adjustment of the construction on the horse's back, several different chamber widths of the saddle tree must be made available 2. According to the invention, a method for adapting a saddle is also provided. This adjustment takes place in several steps:

2.1 First of all, the current condition of the horse with regard to its muscular tissue and any skewed position must be determined. It is determined in particular whether the lateral deviation of the vertebral line shown in FIG. 2D is already present. Furthermore, the pelvic position of the horse is checked for its symmetry from the rear view. The symmetry of the shoulder and the position of the longest spinous processes in the withers are also checked from behind over the croup. There are often abnormalities in the shoulders, as already documented in WO 98/29331.

At the same time, the rear edge of the scapular cartilage in the longitudinal axis of both sides should be checked in the shoulder area. In almost all cases, the shoulder that appears more massive when viewed from behind is also set further back in the longitudinal axis than the other. The explanation for this already results from FIG. 2B, namely that the shoulder located further back is displaced outwards by the rib cage, which widens considerably in this area. The basic rule can be: If the left shoulder is further back and appears more massive from behind, the horse is "right-handed" in the forehand. The reverse applies to the right shoulder.

2.2 Also check the hoof position, which allows information about the condition of the back and the left or right handedness of the horse.

2.3 Furthermore, the muscles are to be assessed with regard to their expression, tension and mobility. The contact pattern of the saddle can be determined, in particular, by checking tension in the shoulder and back area. Tension in the shoulder area indicates that the saddle is stuck behind or on the shoulder. This results from the center of gravity being shifted too far back, which means that the saddle is permanently pushed against the shoulder blade ends. Furthermore, mobility in the neck or neck is tested. Other criteria to be checked are mobility in the bulging of the thoracic spine and in the bulging of the area of the lumbar-cruciate ligament pelvis.

2.4. A further step of the method according to the invention is the appropriate selection of the saddle tree. The selection corresponds to general guidelines, but with one major difference: As already described, the saddle tree is not adapted to the actual condition of the horse in terms of shape, but rather to the horse in its ideally muscled and unsparing condition. This selection gives the horse a form in which it can "develop" positively and find the necessary freedom.

2.5 The chamber width still to be selected corresponds to the cross section of the front profile of the saddle layer. Normally, the muscular condition and the shoulder width are not taken into account when making the selection, so that the yardstick between the saddle and the upper edge of the spinous processes is often used as the yardstick.

2.6 The first padding step according to the invention is carried out symmetrically. After the horse has been saddled, the following criteria are checked in step motion on straight lines under the tab:

First, there is a cycle check on hard ground. If the footing on the forehand or hindquarters is unevenly hard and the footing point is different, this must be compensated. Basically, the horse with its side facing away from handiness is harder and farther. During the demonstration phase, the leg facing away from handedness is pulled forward faster. In addition, an assessment of the shoulder freedom of the saddle is possible during the demonstration phase of the two front legs. If the leg is shown crooked and just above the floor, the saddle on the shoulder is too tight. If the leg is delayed and briefly brought forward, there is too much pressure on the trapezius muscle of the horse's back.

When checking the freedom of the shoulder, when the horse is walking, there must be no pressure situation between the front edge of the saddle and the edge of the shoulder blade stand that could change the position of the saddle. This should also be done on both shoulders on straight and curved lines.

The balance is also checked visually and using buttons. If the contact pressure on one side is higher, so that the saddle threatens to tip over on the opposite side, this is compensated for by padding on the respective side.

The further checking of the horse's movement in walking, trotting and galloping is carried out with the rider's influence on the reins as little as possible, so that the horse can better assess the degree of balance currently present.

Claims

claims

1. Riding saddle consisting of saddle tree, gullet and saddle cushion, characterized in that the saddle tree comprises a rigid seat shell, a spring plate and a panel plate, which are each releasably connected to one another, and that the saddle cushions include interchangeable padding elements, one to the longitudinal axis of the horse enable asymmetrical padding.

2. Riding saddle according to claim 1, characterized in that the saddle tree also comprises interchangeable heels which are detachably connected to the other elements.

3. Riding saddle according to claim 1, characterized in that the components of the saddle tree are arranged one above the other in the order seat shell, spring plate, panel plate.

4. Riding saddle according to claim 2, characterized in that the components of the saddle tree are arranged one above the other in the order of the seat shell, alternate costumes, spring plate, panel plate.

5. Riding saddle according to one of claims 1 to 4, characterized in that the spring plate is elastic and the surface area of the seat shell protrudes at least along a partial edge region.

6. Riding saddle according to one of claims 1 to 5, characterized in that the panel plate is elastic and the surface of the spring plate and the seat shell projects at least along a partial edge area.

7. riding saddle according to one of claims 1 to 6, characterized in that the outer edges of the panel plate is provided with slots.

8. Riding saddle according to one of claims 1 to 7, characterized in that the changing heels on the side facing the seat shell have a positive connection with the seat shell and have different shapes on the side facing the horse's back.

9. Riding saddle according to one of claims 1 to 8, characterized in that the panel plate is designed to be connectable to the saddle cushion.

10. Riding saddle according to one of claims 1 to 9, characterized in that the saddle cushions are formed with padding pockets, which have insertion pockets for the panel plate.

11. Use of a riding saddle according to one of claims 1 to 11 for the active muscular modification of an asymmetrically muscled horse.

12. A method of fitting a riding saddle according to any one of claims 1 to 10 comprising:

12.1 Checking the muscling of the horse with regard to deviations of the vertebral line from the longitudinal axis of the horse

12.2 Checking shoulder symmetry

12.3 Checking the hoof position

12.4 Mobility test

12.5 Selection of the saddle tree with the proviso that the vertebral canal remains free to a width of 6 to 8 cm, the shoulder does not come into contact with the saddle tree and the costal arch can serve as the wing of the saddle, the cross section of the chamber width for the front professional corresponds and the lower swing of the tree follows the rib curvature and the center of gravity is above the center of gravity of the horse and the swing and angulation of the lateral wings corresponds to the rib curvature

12.6 Symmetrical padding by "filling" the space between the saddle tree and the horse's back with padding material, whereby the spinal canal is left out

12.7 Checking the horse's rhythm in the gait step and, if rhythmic impurities are found, optional asymmetrical padding on the side of the lower contact pressure

12.8 repetition of step 12.7 as long as clock impurity is found

12.9 Checking the horse's rhythm in the trot gait and, if the rhythm is found to be imperfect, optional asymmetrical padding on the side of the lower contact pressure

12.10 Repeat step 12.9 as long as clock impurity is found

12.11 Checking the horse's rhythm in the gait gallop and, if rhythmic impurities are found, optional asymmetrical padding on the side of the lower contact pressure

12.12 Repeat step 12.11 as long as clock impurity is found.