PT2478790E - Gravitational footwear - Google Patents

Description

DESCRIPTION

The invention relates to footwear, which ensures the energy accumulation by means of a spring, compressed under the mass of the wearer's body and the use of that energy when the spring is released to push the user's foot upwards. This shoe can be used daily as sports footwear specifically for running, jumping, skiing, sliding, shoes with wheels, etc., as well as a device that complements conventional shoes to provide energy accumulation. The known device, which facilitates jumping by means of an arcuate (arch-shaped) spring, which accumulates energy when compressed and communicates that energy when the spring is released, has been designed and patented by Alexander Borg (see US 6719671 or the application WO 01/05469 A1).

This removable device comprises: an arcuate blade spring designed for recurrent deflection (compression, flexing, spring-end convergence) under the application of gravity forces of the user's body mass. With the accumulation of a part of this energy and the release (extension, spring distancing) when the mass of the user's body is withdrawn from the spring (for example, when the mass of the user's body is communicated from one foot to the other) use of accumulated energy and its application to the user in the form of repulsion forwards and upwards; the lower part of the spring is provided with a support element for interacting with the support surface; a lever-hinging mechanism located on a concave side of the arcuate spring and secured to the user's foot and especially to the knee, comprises: a base for accommodating the user's foot (platform, support), joined at least two points of the spring and equipped with a support element. • central support (rigid vertical element), fixed to a knee of the user with a knee brace and attached at the top to the top of the leaf spring by means of a hinged-lever mechanism, and rigidly attached to the base, located in a 90 ° angle against center bracket; • connecting rod hinged between the front part of the base and an area of the lower spring arm, distally approximately 1/3 of its end with the support member, the connecting rod including hinged to a spring interacting shackle; • a support element for supporting the base in a position relative to the central support; The accumulation created by a user (aisle) is communicated to the spring in two ways. The first form provides communication through the lever mechanism and the upper securing member on the raised part of the spring, then the latter spring through the support element on the support surface. The second provides communication through the shackle at the bottom of the sheet water. The weak point of this device is the inability of its use, impossibility of its use in daily life. The only possible way to move is to jump or run. Thereby, the device eliminates a number of technical imperfections, including from an unreliable attachment of the base to the foot: the obliquity is still possible, even with a support device when the mass of the user's body becomes larger. Another known device is designed for jumps. It represents the advanced design described hereinbefore developed by Tea-Hyuk Hoon, patented in several countries (see US Patent 6840893).

This known device includes: - arcuate leaf spring directed towards recurrent flexible deformation (compression, bending, convergence of spring ends together) under the gravitational effect of the mass of the wearer's body with accumulation of some of that energy and release extension, distancing the ends of the spring from one another) when the load is removed from the body of the user on the spring (for example, when the mass of the user's body is transferred to the other foot) with the release of accumulated energy and its application to the user's foot in the form of repulsion forward and upward, a wear resistant support member is provided to the lower spring arm for interaction with the surface; - a lever mechanism, situated on the concave side of the arcuate spring, fixed to the user's foot, especially at the knee, and comprising: base for accommodating the user's leg (platform, support) at least at two points associated with the spring; provided with a cover, which provides secure attachment of the user's feet to a platform, i.e. acting as an upper shoe part and / or fastening elements; * vertical element (central support) fixed to the wearer's knee with the help of striped knee bands which partially embrace the wearer's shin and attach to the upper part of the top of the leaf spring, while the lower part is fixed rigidly to the platform, located in relation to the vertical member at an angle of 90 °; * joint-connection between the front part of the base and the area of the lower spring arm, slightly withdrawn (about 1/3) from its end by a support member; one of the elements of this connection is installed with the possibility of stopping with a spring in its compressed state; The operating principle of this device is similar to the principle of the device patented under US Pat. No. 6719671. The basis of its operation is defined by the curvature of the spring under the action of the potential and kinetic energy of the mass of the user, while accumulating energy and followed by subsequent release of the spring with the simultaneous use of the stored energy and the focus of this energy on the forward and upward movement of the user.

However, the complexity of this device, the inability of its use, the impossibility of use in daily life represents a major disadvantage of this device. Displacement using such a device requires considerable effort, special skills, and a well-developed coordination system. Along with this, the displacement using such a device is only possible through the jump or run. Movement with steps is impossible.

A special footwear, as described in application No. 2008107517 of February 28, 2009, for the adjudication of the patent of the Russian Federation, and the decision to grant the patent was made in accordance with the above-mentioned request was designed to use of the stored energy operating principle by means of the curvature of the spring which rests on the ground or other support surface when exposed to the mass of the user and the subsequent release of energy during the release of the spring using this released energy to push the feet of the user without special extraction devices, but directly in the shoe. This shoe was chosen as a prototype.

Such footwear, shoes, boots, etc., designed with energy storage, induced by elastic deformation, including: - elastic sole, which may have full or partial contact with the support surface; an elastic back part joined to this sole (all made in one piece with said elastic sole), and - retention mechanism for securing the position of the user's foot on the sole, mechanisms which are connected to the sole and back; - wherein the rear part and the sole form a leaf spring of the given flexibility, providing deflection, the rear part and the sole being, simultaneously, leaf spring arms; - wherein the leaf spring elastically deforms from the initial state to a compressed state; - wherein the back and sole are initially at an angle of 90 ° to each other, and - wherein the angle of the leaf spring in its compressed state between the sole and the rear is reduced. The relative complexity of the movements with this device, especially at a wide angle between the spring arms, represents disadvantageous features of such footwear. The load rate, which compresses the spring that is in the form of the sole and the back, is determined by the weight of the wearer, but also by the force of your foot muscles. Generally, the load (the gravitational force exerted by the user's mass and the energy exerted by the muscles) is communicated on the lower spring arm (the impact on the user's foot) or on the lower part of the upper spring arm (the impact on the elastic back, for example, by the heel of the wearer), as a result of which a gravitational influence on the spring in the shoe is insufficiently effective. Displacement when using said footwear with periodic compression and deflection of the spring requires a vertical initial posture of tips, and then lowering the heels to the contact of the sole completely or mainly with the support surface.

This displacement is different from regular contact with the support surface when walking. First, if you are standing on your heel, then drag your full foot down and slide forward over the tip. The construction previously described in U.S. patent 6840893 may serve as a prototype of the spring unit. Includes: - Arched leaf spring provided with a wear resistant surface; - device for sending the gravitational effect on the spring, fixed to the user's foot and comprising a base with a " for housing a foot, joined by a rigid ascending element with the upper part of the spring.

At the same time, it is not the lowest part to house a foot. There is no contact with the bearing surface, being fixed rigid and perpendicular to the ascending element. The distance of the riser is always less than the distance between the upper and lower ends of the spring, even if the latter is fully loaded (with curvature, compression). The disadvantage of the device - the prototype is based on the inability to move in a single step when using said device. It only allows jumping and moving u this can be explained by the fact that the user always has only one support point - the lower end of the spring. The document RU 2 160 571 Cl describes gravitational footwear in the form of shoes or boots with a sole, with energy accumulation caused by elastic deformation, including a spring unit which compresses a flex spring of the given flexibility that flexes from the initial state to the compressed and formed state, wherein the lower part of the spring is a support element, intended to make contact with the support surface and the upper part of the spring is equipped with fastening devices to fix a foot position of the user and to communicate the gravitational effect on a spring of the spring unit, wherein the fastening devices for the communication of the gravitational effect on the spring into the spring unit comprise the attachment of the upper part of the spring to a rigid insole or another member which suspends the user's foot, wherein simultaneously H1> H2 when no load is applied to the spring and H1 = H2 or H1 approaches of H2 when a load is applied to the spring, H1 being the distance between the ends of the spring (1), H2 is the distance from the upper part of the spring (1) to the lower part of the wearer's foot, wherein the spring ( 1) constitutes the basic footwear elements, and the support element of the lower part of the spring within the spring unit is realized in the form of a heel, the sole is realized with the possibility of contacting the support surface when load is applied to the spring, wherein, in the preparation for the next step, the foot is supported on the support surface not only on the spring, but also on the sole. The aim of the present invention is to increase the effective use of the reported gravitational effect to the spring which accumulates energy when bent (compressed) and uses the stored energy for an extra push of the user's feet by optimizing the communication of the load on the spring and allowing the release of energy at a given time along with facilitating movement by prior use of the thrust character of the foot from the heel to the tip.

Another challenge is to create an accessory device of the spring unit type to complement normal footwear; which provides, in addition to the above solutions, the ability to move to the pace of the steps, being supported at two points (e.g., the lower end of the spring and the sole of the regular footwear).

Once the challenge is established, the present applicant considers it appropriate to use the word " gravitational " in the title of the invention.

These objects are achieved by means of gravitational shoes according to claim 1.

Along with this, the sole of the gravitational footwear may be attached to the spring to transfer the load of complementary gravity onto the spring, wherein H1> H3 > H2, when no load is applied to the spring and H3 means the distance between the top of the spring (the point of suspension of the leg) and the point of attachment of the sole. H1 = H2 = H3. H1 and H3 approaches H2 when the spring is compressed. The spring unit may include a plurality of springs placed on its back, on its sides or on the tip of the shoe, when the support element in the form of a heel is wholly manufactured as a part with all or several springs and the number of upper and lower springs may necessarily coincide. The lower back part of the shoe when the spring is compressed may be located in the heel area of the wearer. The lower back of the shoe when the spring is compressed completely fit into the sole. The sole when the spring is free of load can fit closely on the lower back of the shoe and attach to it. The spring may be of various shapes, for example, it may be arcuate, with an additional curve designed to engage the heel of the wearer. It can have a semi-ellipsoidal shape (crushed), etc. The spring may have several cross-sectional shapes. It can be crescent shaped, broad isosceles triangle-shaped section, ellipsoidal shaped section, rectangular, U-shaped element, etc. The cross-section and longitudinal section of the spring may be constant or variable. The material, its physical and technical properties of the spring, can be constant or variable in length, width and thickness. The spring may be made, in part or in whole, of one or more materials: polymers, including polyurethanes, polycarbonates and other compounds, elastomers, etc. The top of a shoe includes a cap that covers the spring partially or completely. The latter may be attached to the upper part by ensuring the possibility of changing the angle of the spring, for example by manufacturing the wavy top or in the form of a set of coherent and extensible elements. The specified objective can be achieved through another type of gravitational footwear, such as a shoe, boot, etc., which accumulates energy used by the deformation and comprising: the spring unit comprising at least one spring of the given flexibility value, which flexes from its free state to a compressed state, formed by footwear elements, wherein the lower part of the spring is the support element designed for contact with the support surface; The claimed gravitational footwear is characterized in that the bending spring constituting the basic elements of the footwear, for example a buttress or a part of the buttress, side members, the heel, etc., when the traditional continuous sole is not provided with a spring (although some of the options may provide a sole that represents an element of the lower part of the spring) and the heel (part of the spring) together with the sole represents a support for contact with the surface.

In most fabrications, the heel attaches directly to the sole. But, when the spring compresses, the heel of the wearer next to the sole can be based on the lower part of the spring heel. Various fabrics provide the lower support part of the spring realized in the form of a heel adjusted to the sole or in the form of a sole only. One of the options provides that during the deformation of the spring, the heel can approach the outer side of the sole or even join. The main advantage of the spring unit, characterized by its ability to be used as a device that fits a common shoe, is the fact that the user has the possibility of accumulating energy divided by the bending spring, the lower part of which is in the in most cases, a heel (support part) and the upper part obtains the gravity load of the wearer's mass, and use this energy to facilitate movement. Along with this, the displacement, as provided by the claimed footwear, can take place in a simple manner by coupling not only to the support end of the spring but also to the sole of the footwear.

Thus, the principle of accumulation and release of energy in the claimed footwear and in a spring unit seems similar to the principle of the removable devices to improve the hop and the run: the arcuate spring is deformed with the weight of the user, accumulating energy, and then , when released it transfers energy to the user by pushing the foot forward and up. However, the user's foot is not engaged in its movement when these devices are used.

Passively the foot rests on the support, which does not come into contact with the support surface.

In the gravitational footwear claimed by: - the implementation of the spring in the form of elements of the footwear (buttress, bead and other elements which are an integral part of the shoe) or the use of additional springs, which does not exceed traditional footwear; a " gentle suspension " of a foot in the gravitational footwear in the absence of contact of a shoe with the support surface (on the collar and / or the insole, etc.) - compression of the spring with the contact with the spring support element - generally the heel- (the combination of 'heel and sole', only the sole) with the support surface can be achieved by transferring the gravitational effect on the upper part of the spring and / or on the lower part of the spring before the heel by the impact ( support) of the heel of the user and / or the transfer of the gravitational effect directly onto the lower back to which the sole is attached. - foot support on the support surface when preparing to take the next step not only on the spring (heel) but also on the soles of a shoe, as well as providing the opportunity to attach the compressed spring to the conservation of its energy stored up to the repulsion of a foot and separating it from the soil ensures the solution of the problem - increase the effective use of gravitational effect - and facilitates the movement due to the preferential use of the traditional nature of the movement from the heel to the tip, running or jumping, but at the normal pace.

This applies to the spring unit. The footwear of the spring unit can be manufactured by hand or at the factory. Therefore, it meets the criteria of " industrial applicability ". The essential point of the present invention is illustrated by the Figures which show the layout options of the main footwear options. Figures 1a, 3a, 4b, 5b, 6a, 6b, 7a, 8a, 8b, 8c, 9c, 10c, 11c, 12c, 12c, 12c, 13c, 13b, 14, 17, 21 are not part of the invention. Most of these figures only illustrate the basic elements of the footwear to facilitate understanding of the essence of the claimed objects, while the secondary (uppermost part of the footwear, structure, etc.) is not shown, the wearer's foot is shown in fine lines :

Figure 1 - Gravitational spring footwear, located on the rear side of a foot, the lower part of which is a heel, while, as shown in Figure 1, the gravity load communication on the upper end of the spring through the collar and the part of the spring by the heel of the user; Figure 1 -communication of the gravity load on the upper end of the spring through the collar and an insole and on the lower part of the spring by the heel of the wearer, when the insole is attached to the sole;

Figure 1B - communication of the gravity load on the upper end of the spring through the collar and a hanging element attached to the collar in the form of a collar and on the lower part of the spring by the heel of the wearer; Figure 16 - communication of the gravity load on the top of the spring through the collar and insole, which partially covers the wearer's foot and the lower part of the spring by the wearer's foot;

Figures 2 - Gravitational footwear supplied with a spring, located on the back side of a foot, whose lower part is a heel, and with a sole, attached to the lower part of the spring in the back of the heel: Figure 2a - gravity load communication on the upper end of the spring through the collar, Figure 2b - communicating the gravity load on the top of the spring through the insole, which completely covers the wearer's foot;

Figure 3 - Gravitational footwear provided with a spring, located on the rear side of the wearer's foot, the underside of which is a heel, and the intermediate part has a complementary curved portion. Communication of the gravity load on the top of the spring through the collar;

Figures 4 - gravitational footwear supplied with two springs, fixed to the sides, wrapping the user's foot on the sides and supplying the user's heel in the form of complementary curved parts, supporting elements protruding from the heel-shaped spring: Figure 4a - communication of the gravity load on the top of the spring through the collar and the suspending member in the form of a strap which embraces the foot attached to the collar, 4b - communication of the gravity load on the upper part of the spring through a narrow collar and the insole which partially covers the foot of the wearer;

Figure 5 - Gravitational footwear supplied with two arcuate springs that embrace the user's foot, fixed on the front of the shoe and surpassing the heel of the user, whose lower part is the heel, the communication of the gravity load on the upper part of the spring through the collar and a joined insole, which partially covers the foot of the wearer;

Figures 6 - gravitational footwear supplied with two L-shaped springs which are on the sides of the user's foot, the underside of which is a heel: Figure 6a - communication of the gravity load on the upper part of the spring fixed to the front through the collar, and Figure 6b - side view and rear view, the springs are joined together at the bottom, communication of the load of gravity on the top of the spring fixed on the sides through the collar and a attached insole that partially covers the foot of the user;

Figures 7 - gravitational footwear supplied with a plurality of springs, located at the rear and at the sides, the lower parts of which protrudes bearing the elements in the form of heels: Figure 7a - communication of the gravity load on the upper part through the collar, 7b communicating the gravity load on the upper part of the spring through the collar and a joined insole partially covering the foot of the wearer;

Figures 8 - gravitational footwear represented by a man shoe provided by a spring located at the back of the wearer's foot, the underside of which is attached to the sole (wide black line): Figure 8a - communication of the gravity load on top of the and Figure 8b - communication of the pregnancy load over the top of the spring through the collar and an insole partially covering the feet of the wearer; 8c -communication of the gravity load on the upper part of the spring through the limb and a suspended element attached in the form of a strap which surrounds the foot of the user;

Figure 9 - gravitational footwear represented by a man's shoe with his instep covering the wearer (see the contour of the instep), provided with a spring located on the back of the foot of the wearer whose lower part is joined to the sole (heel);

Figure 10 - Gravitational footwear represented by a man's shoe with his instep surrounding the user's foot, provided with two bow-shaped springs, located on the sides, the lower part of which joins the sole (heel);

Figure 11 - Gravitational footwear provided with a spring locator and a foot that surrounds the user's foot: Figure 11a - The spring is located at the rear of the foot of the wearer, the lower part of the spring is attached to the heel and a sole element, gravity loading communication over the top of the spring through the collar and an insole partially covering the foot of the wearer; Figure 11b two springs located on the sides, communication of the gravity load on the top of the spring through the collar and an insole partially covering the foot of the wearer;

Figures 12 - gravitational footwear represented by a woman's shoe: Figure 12a - The spring is located at the rear of the foot of the wearer, the lower part of the spring is a heel, communication of the gravity load on the upper part of the spring through the collar and an insole, Figure 12b - the spring is situated at the rear of the user's foot, the lower part of the spring is a heel, the spring attaches to a sole, communication of the gravity load on the upper part of the spring through the collar Figure 12c - two side springs, the lower part of the spring represents a sole / heel, the end turns back, the communication of the gravity load on the upper part of the springs through the collar, and Figure 12d - two lateral springs, the bottom of each spring is a heel, turned back, the spring attaches to the sole, transferring the gravity load over the top of the spring through the collar, Figure 12e - two springs surrounding the foot of the (the heel is combined with a sole), the spring is further equipped with a heel support, the communication of the load of gravity on the upper part of the springs fixed on the front through the collar, 12e - 12f version, footwear represented by ballet shoes; in Figures 13 - a gravitational footwear with a spring, located at the rear of the foot of the wearer, the lower part of which is a heel with the adjacent part or sole attached thereto, or only the sole, Fig. 13a - communication of the gravity load on the top of the spring through the collar; Figure 13b - transfer of the gravity load over the top of the spring through the collars and an insole, which covers the foot of the wearer;

Figure 14 - arrangement of the spring unit for use with normal shoes;

Figure 15 - a gravitational footwear with a spring, located on the rear side of the foot of the wearer and divided into two elastic spring elements arranged at an angle to each other: the heel and sole at the end thickening;

Figure 16 - gravitational footwear similar to that described in Figure 15, except that it is designed with the space between the sole and the easily deformable cushion heel, such as a porous material;

Figure 17 - Gravity footwear supplied with two springs located on both sides, the ends of which are attached to the elastic sole;

Figure 18 shows cross-sectional shapes of the spring;

Figure 19 - Options of woman sandals with a collar, various support elements and the spring surrounds the back side of the wearer's foot. The lower part of the spring is a heel with a C-shaped cross-section;

Figure 20 - Layout of women's sandals with L-shaped side springs at different loading stages: phase 1 - the foot does not rest, the heel appears below the sole, phase 2 - the foot rests, the heel is compressed ( curve), the heel lifts the foot;

Figure 21 - the best performance of a collar and an insole (side view and rear view);

Figure 22 is a spring unit with two springs on each side, the ends of which are attached by the element under the heel which is underneath the back side of the sole of a normal shoe;

Figure 23 shows an arrangement of a woman's sandal with a spring of varying cross-section, which surrounds the lower part of the foot of the wearer on the rear side, being attached to the spring. The claimed gravitational shoe may appear in the form of a shoe, a boot or a tall boot, a sandal, etc., including as a mandatory element at least a flexible spring of flexibility, which flexes from the initial state to a tablet and using energy pushing the user's foot when released or accelerating due to the synergistic effect when the foot rotates from the heel to the tip. This spring 1 in the claimed shoe or attaches to traditional shoe elements, such as the lower back part or a heel, is a part thereof, or an inner or outer element of the complementary shoe. For example, the upper part of the spring can encircle the foot of the wearer, but at the same time it can go inside the shoe, be cooked inside the shoe or fasten from the upper part of the shoe (Figures 9, 10, 11) . The lower part of the spring is a support element which contacts the surface on which the user is walking. Most of the claimed shoe embodiments of such a support member are designed as a high heel 2 (Figures 1-7, 12, etc.) or a low heel 2 (Figures 9, 10, 11). However, embodiments of the spring support member are possible in the form of a heel and sole, and only in the form of a sole (Figures 13a and 13b).

This description does not use the term " moist support " although the spring used typically includes two supports on opposite sides of the deflection curve. The claimed gravitational footwear, in addition to said spring 1 above, includes the usual elements for suitable shoes: sole 3, sole 4, etc. The toe 4 of a shoe provides protection of the foot of the wearer against adverse impacts, fixes the position of the foot of the wearer and provides the opportunity of a regular curve of the spring 1 without damage to the elements of the upper part of the foot 4. That chest of the foot 4 includes a fastening device for securing the wearer's foot, the instep 4 and the fastening devices are joined by a spring 1 of this type, sole 3 and other elements of the shoe. Said fastening devices may be the rigid part of the instep of the shoe, for example rigid bands, etc. and / or fasteners such as straps, straps, ties, covers, velcro, brackets, etc.

In separate options, the toe of a shoe may only represent a fastening device, such as when sandals represent the embodiment of such a shoe (Figure 19).

This shoe toe 4 of the shoe provided with fastening devices in addition to securing the user's foot and its protection from environmental impacts should provide communication of the action of gravity from the mass of the user's body on the spring 1, thus are special elements in the claimed footwear. The form of this realization may be different.

One of the options provides a collar 5 which partially or completely surrounds the wearer's leg (cinnamon) and attaches to the top of the spring 1 to transfer the action of gravity onto the top of the spring. In this case, the collar 5 may be attached to the spring 1 in a small section (Figures 2a, 2b), or in an enlarged section (along the legs) (Figures 1, 3). In the first case, the load is immediately applied to the spring, in the second case the load is distributed along the length of the collar 5. The collar may be in the form of a relatively narrow elastic ring or semi-ring (Figures 1d, 2b, 4b, 7b, 8a, 8b, 8c, 13b). There may be a number of such rings (not shown in the Figures). There may also be other options which are not considered in the present application document for a load of point or distributed gravity on the upper part of the spring 1. The collar 5 assumes the function of transferring the load to the upper part of the spring a from the cinnamon, where the user's foot hangs down on the collar, to the firm embrace of the cinnamon by the collar (coupling), or due to both, thickening and firm hugging simultaneously.

When the spring is free (without ground support) and when the spring support member contacts the ground, the user's foot reaches said collar 5, although the spring may touch the lower part of the spring 1 (Figures 1, 4a ). When a support element (the lower part of the spring, jumping) rests on the ground, the gravity load communicates from the mass of the user's body through the collar 5, or other elements, with the spring 1.

In high boots, the collar 5 can be placed under the knee in high shoes - in the cinnamon. In a shoe or tennis shoe, the collar 5 can be placed above or below the ankles. The toe of a shoe may serve as a collar 5. The width of the collar 5 may vary over a wide range; among others the collar 5 may encircle the complete upper part of a shoe, for example up to the ankles. The collar 5 may be attached to the spring 1 only at its top (point load), or along the entire height of the collar, or at the top of the collar (distributed load).

In another embodiment, a rigid insole 6 is provided and another soft element, which supports the user's foot, touches the top of the spring 1 to transfer the action of gravity to the top of the spring. In this case, the application of the load to the spring 1 can be punctual (insole 6 unit in a small area) or distributed in various lengths of the spring, an example through an elastic strip that goes from the top to the bottom, joining the spring 1 to in the right and left portions of the spring. The insole 6 may completely cover (Figures 2b, 12a) or partially (Figures Id, 5, 8b, etc.) the wearer's foot. The partial coverage of the user's foot (suspension) may be provided through the use of a strip 7 (Figures 1c, 4a, 9). The embodiment of the insole 6, which partially covers the wearer's foot and provides a one-step free bend, as shown in Figure 21, seems the best fit. The upper part of the insole 6 may be circumferentially attached to the collar, providing a uniform application of the gravity load of the insole to the collar, although the use of a durable material such as insole allows withdrawal from the collar 5 suspends the insole 6 directly to the upper part of the spring 1. The attachment of the insole 6 to the collar 5 or to the spring 1 may be made by any known means.

The following options for shared use of collar 5, insole 6 or strip 7: • collar (elastic ring or semi-ring) 5 insoles 6 (Figures 1b, 2b, 8b, 12a, 13b); • collar 5 and strip 7 (Figure 4a); • collar 5, insole 6 and strip 7 (Figures 1c, 8c);

One of the conditions defining the efficiency of gravitational footwear is the necessity of securing the main support with one foot through the same communication, of the gravitational effect on the hinge of the spring 1. In this situation, the spring 1 should be compressed properly and be capable of accumulating the maximum amount of energy, when the user's foot does not rest on the ground, remains " glued " the collar 5 or the insole 6 or the collar 7 on top of the bending spring. When a foot is lowered to the contact of a jump 2 with the ground, due to the gravity effect of the mass of the user's body on the spring, the latter deforms (curve) and the foot gradually descends and begins to rest on the ground by means of the jump 2 and the sole 3.

In this sense, the relation must be obeyed: H1> H2 when no load is applied to the spring, where

Hl - distance between the ends of the spring; H2 - distance between the top of the spring at the bottom of the foot.

When the spring is charged H1 = H2 or approaches H2.

The greater the difference between these values, the more the spring is curved (compressed) and the greater the pushing or sliding effect. Perhaps the difference indicated between H1 and H2 is limited by the shape of a shoe and the conditions of its utility. When the user's foot rests on the ground by bending the spring 1, the distance between the two ends of the compressed spring is equal to or close to H2. The spring may be attached to the collar or insole at any point on the circumference of the wearer's foot (for example, the back of the foot) (FIGS. 1a, 1b, 1c, 1d, 2a, 2b, 3, 8a , 8b, 8b, 8c, 9b, 12b, 13a, 13b) on the sides (4a, 4b, 6b, 7a, 7b, 10, 11b, 12c) or the front part (Figures 5, 6a, 12e, 12f).

If there are two springs, they can be symmetrical.

The springs may surround the user's foot at the rear (Figures 1a, 1b, 1c, 1d, 2a, 2b, 3a, 8a, 8b, 8c, 9a, 12a, 12b, 13a, 13b), being located on the sides (Figs. 4a, 4b, 6a, 12d, 12e, 12f), or pass from the front to the side of a shoe (Figures 5 and 22), passing from the sides to the rear side of the shoe (Figures 4a, 4b, 12c) and others. The spring can be mounted anywhere on the circumference of the shin of the user and is only one.

In the case of side springs, the latter may be joined by an element 8 under the jump, through which the spring 1 can collect the load. This element 8 under the heel can pass the pivot 2 volumes, joining the lower parts of the springs, but can be represented by a frame-shaped connecting element separated between the support parts of the springs (Figure 6b). The spring 1 may be made of one or more materials, for example polymers (polyurethane, polycarbonate, etc.), compositions, elastomers and other elastic materials, whereas the separate elements of the spring 1 may be made of different materials, for example , the main part of the spring can be made of a composite material having the necessary high elasticity (stiffness) properties with high bending stress, while the heel 2 can be made of a less expensive but high wear resistant material. The cross section of the spring 1 may be different. Some embodiments of the cross-section shown in Figure 18 (the user's foot is placed on the right side of the section, meaning that it is covered by the spring). For example, as shown in Figure 18a, the section is highly enlarged at the base of an isosceles triangle with a slightly concave base; in Figure 18b - a triangle with a strongly concave base, Figure 18c - a rectangle with a strongly concave base, and Figure 18d - an enlarged rectangle with a slightly concave base; three springs, which surround the user's foot. The cross-section of a spring may be constant along the longitude or alternate. For example, the spring, located at the rear of a foot, has a C-shaped cross-section (partially encircling surrounding) and sliding in a striped, circle-shaped heel at its bottom. Two lateral springs with the rectangular cross-section can be combined to form a common or medium-sized rectangular section S in the lower part of the spring.

The elastic properties of the spring may be constant or variable in the length and thickness of the springs, for example, the heel material 2 may be stiffer than the rest of the spring.

One form of the spring 1 may be different: - having a simple arcuate shape (arch shape) (Fig. 1a-d, 2a-b, 12b); - arch with additional curved sections, such as the sub-heel section (Figures 3, 4a, 5); L shaped (Figures 6a, 6b, 20); shaped like a semi-ellipse (Figures 9, 10, 12c) - arch with additional deflecting elements, representing a single or other support element (Figures 12b, 12d, 12f). The notion of " spring " mentioned in the claimed gravitational footwear is not limited to a single spring. There may be more. The upper part of a spring 1 may be located at the back of a shoe, especially if only one shoe is used, especially if only one spring is used, another embodiment provides multiple springs (two or more) surrounding the shoe. (7a, 7b) of the wearer's foot on the sides (Figures 4a, 4b, 5a, 6a, 6b, 10b, 12b, 12c, 12d, 12e, 12f) or along the rear and side sides of the wearer's foot. Various springs may be joined together, such as, for example, in the area of a support element (heel or sole). In this case, each of the springs may have an upper part and two or more lower parts and vice versa. However, the illustrations do not cover all possible options, both in number of springs used and in their possible location.

In the spring 1 with a traditional soft arc, bending is provided mainly affecting the upper part of the spring 1, with the heel rest 2 on the support surface, for example in the ground.

However, communication of the gravity load on the lower part of the spring 1 is possible from the impact created by the heel of the user on the heel 2, which rests on the support surface. In this type of load spring, it can be adjusted with a special projection of the lower part of the heel, while the heel can rest on the slightly curved bow (excluding the projection).

When the shape of a spring is complicated, for example when it has the shape of an arc with an additional flexion (projection), which extends along the contour of the wearer's shuttle, communication of the forces of gravity can be made at the top of the spring 1 and further with the heel 2 on the support surface, and by means of an additional heel support (flexion, additional projection) on the lower part of the spring. At the height of the heel 2, which is the lower part, the bending of the spring 1 may be different.

In women's shoes, heels can be high enough, for example, 5-7 cm or more. The best of all such heel classes are those shown in Figures 12a, b, c, d and in the Figures in Figures 19, 20.

In men's and sports shoes, the height of a heel may be smaller, for example 1-3 cm (Figures 9, 10). Various embodiments provide a heel, which, as in the case of any other type of shoe, a support for the heel of the wearer, does not extend over the inner surface of the sole (Figures 8a, b, c). In these embodiments, the lower end 2 of the spring 1 partially surrounds the heel of the wearer (functions as a support element under the heel of the wearer, which means that it is a heel class) and unites with the sole 3. The loading of the upper part of said spring can be carried out with the aid of the collar 5 and / or the insole 6 and / or the contour strip 7. As H1> H2, the foot is suspended, there is a space between the sole 3 and the foot of the wearer. When the spring bends, the foot rests on the sole 3 and the lower end of the spring 1. There is also proposed a shoe option provided with a foldable heel 2 (which moves close to the sole until its complete coupling). In this case, when the gravitational effect is imparted to the spring, the heel 2 gradually folds and approaches the sole 3 (Figures 2a and 2b). When the heel is turned towards the tip, the sole can approach the heel.

In the lower part, the spring can be divided into spring elements located at an angle between them: the heel and the sole (Figures 15 and 16). This embodiment should firstly increase the efficiency of the energy storage (two springs), and secondly, avoid its misuse due to the communication of energy from the heel to the sole when the heel begins to separate from the support ( there is no need for a third fastening device) to accelerate the bearing from the heel to the tip. As shown in Figure 16, the space between the heel and the sole is filled with a material easily deformable, for example as porous, which should prevent foreign bodies from entering between the springs (stones, dirt, etc.). Figure 17 shows the embodiment of a shoe (or spring unit), wherein the springs, which surround the wearer's foot, are attached to the sole, which is also a spring. This should help facilitate and accelerate the process of rolling from heel to toe. The option, when the role of the support element is achieved by the heel, combined or attached to the sole or pivot of the spring is the complete sole or a part thereof (Figures 13a, b). In the latter case, its length may be equal to or greater than the length of the user's foot, and the movement is achieved by initial stroke from the heel to the tip (to the end of the spring 1). The toe of the shoe 4, in addition to the mandatory elements, may be an outer insole, which covers the spring 1, or attaches to the spring, or passes under the spring and provides the possibility of periodic flexing. This insole may be corrugated or consist of separate ring-attached or attached ring-shaped elements. The insole may cover part or all of the wearer's foot.

Along with this, the toe of the shoe 4 may include an inner part, directly adjacent the foot (lining). The inner part can not be attached to the spring 1 and may not be subjected to deformation during bending. In the latter case, the requirements for materials are common. If the lower part is attached to the upper part of the spring 1, the material and / or the interior design must allow it to deform when the spring is compressed. The sole 3 can fit in the shape of a normal shoe and ensure a comfortable foot accommodation, protection against mechanical damage. The sole (its inner surface), as in other classes of footwear, must be sufficiently durable. The sole 3 can be joined with the lower part of the spring 1 to provide additional communication of the compression forces from the foot to the spring. The joint can be made, for example, as a ball-and-socket joint, which provides the possibility of an angle from a front part of the sole 3 down to the support surface. At the same time, the sole 3 in its initial position is placed horizontally, and when walking the front of the sole inclines to support the foot and to rotate from the heel to the tip and to push.

According to one embodiment, the foot may be immediately adjacent to the sole 3 (without separation), since it does not rest on the ground. From the beginning of ground support, gravitational forces are distributed and affect the upper part of the spring, through the collar and the lower part of the spring by means of a heel of the user through the back side of the sole or only the lower part of the spring (Figures 1b , 1c).

According to a further embodiment, a foot in its initial position is not adjacent to the sole 3, and does not rest on the ground (bearing surface), and a space is maintained therebetween (Figures 2a, b, 8a, b, c, 12b, d), and the following relationship H1> gt; H3 > H2, where H3 is the distance from the top of the spring (the point of suspension of the foot) to the point of attachment of the sole. When the spring 1 is folded, the space between the foot and the sole is selected first, and then there is the space between the sole and the support. This solution gives a larger difference between H1 and H2 when it does not apply to the spring. The spring 1 may be provided with an attachment device 10; which secures the spring 1 when it is compressed and releases the spring at a given moment, such as when the user pushes the foot away from the support surface (carries out the next step). It is necessary for this that the stored energy is not wasted if the foot of the heel is turned to the tip; whereby when the spring separates the carrier for a period of time, which exceeds the spring return to its initial state, the energy must be lost. It is possible that any embodiment 10 of fixation and release device known by the current technology. In this form, Figures 11a and 11b show one of the possible mechanical devices: hook-shaped fastening devices 10 which locks the spring 1 and is released under the action of a foot on the drawbar 11.

An action for self-locking of the spring, equipped with hook couplings ("Velcro" type), joined in the spring bending to the adjacent element of a shoe. The forced release of a spring is possible by changing the angle of inclination of the shuttle of the user; which happens when the user is ready to separate the foot from the support (bearing).

The options of the securing device 10 shown in the Figures are not necessarily exhaustive of all the embodiments. The fastening device 10 may be magnetic or be made from electronic devices. The main condition is that the clamping moment must satisfy the maximum deformation of the spring, and its release must respect the momentum of the user's foot pushing away from the support surface. Figure 12d shows woman's shoes, whose sole is attached to the spring, while the back of the sole extends beyond the heel (lower part of the spring) and serves as an additional support under the heel of the wearer. Similar structures are shown in Figures 12e and 12f. These options can be used as efficiently as ballet shoes. The spring unit (Figures 14, 22) may be used as a device for a normal shoe, which accumulates gravitational energy and provides the opportunity for running (jumping) and walking by rolling from heel to tip. The spring unit is a device, wherein its design corresponds to a spring unit used to be fitted to the claimed gravitational footwear. It comprises at least one spring 1 and a fastening device in the form of a collar 5 described hereinbefore which surrounds the wearer's shin, or a soft (unstretched) rigid element 7 supporting the wearer's foot. The latter guarantees a gentle suspension of the user's foot relative to the top of the spring 1 and the communication of the gravitational effect on the spring 1. The ratio of the dimensions between the ends of the spring 1 when no load is applied (discharged) H1 and distance . The spring unit is a device which basically corresponds, due to its design, to a spring unit used in claimed gravitational footwear. At least one spring 1 and a spring attachment device, as described above, the collar 5 covering the wearer's shuttle, or a soft rigid (untensioned) element 7, which supports the wearer's foot, through which ensures smooth suspension of the user's legs to the top of the spring 1 and transmitted to the gravitational effect of a spring. The relationship between the ends of the spring 1 in the free (unloaded) state and the H1 and the distance from the suspension point to the underside of the shoes soles 3 is normally H2 is similar to the above: H1> H2.

During loading of the spring, a distance, the user's leg begins to focus not only on the end of the spring holder 1, but on the sole of the three normal shoes. The claimed gravitational footwear is used as follows.

A user places shoes and, if necessary, secures the position of his foot by means of a special fastening device, for example, secures the collar 5 and the sole 3 with straps.

After the shoes are in place, the user stands on the surface of the carrier, and the springs 1 are then compressed and each foot rests on the heel 2 and the sole 3.

At the beginning of the movement, the user lifts one foot while still resting on the other. When a foot of the spring is raised inside a shoe, it is released and H1> H2, the user's foot touches the upper part of the spring 1 on the collar 5, the insole 6 or the strip 7. Then, when moving to the front, the foot touches the support surface by means of the projecting support element of the spring, for example, through the heel. Upon contact with the carrier, the user transfers a portion of his body mass onto the foot compressing the spring 1. The distance between the ends of the spring 1 equals the distance between the point of suspension and the lowest point of the foot of the user H2 or approaches it. The compressed spring 1 accumulates energy. When it moves further, the user's foot rotates from the heel to the tip to push the tip away from the holder. If the characteristics of the spring are selected so that the spring flexes over a period of time, which exceeds the rolling time from the heel to the tip, the energy of the spring is not lost and, at the moment of separating a tip from the support pushes the user's foot forward and upward. If the spring is released quickly, it would be advisable to use additional devices, such as a fastening device 10, which ensures the compression of the spring 1 until the moment of repulsion of the spring. The fastening device 10 can be released under the effect of the spring in the special device, for example the trailing rod 11 attached to the fastening device and provided with a concave section in the front part further than the spring. If the concave section is pressed, the length of the trailing rod 11 is gained and the trailing rod pushes the catch hook 10 out of the lock with the spring 1.

To reduce accumulated energy losses, it is possible to use two springs and two support elements (lower parts, spring arms), one of which is a heel, and the other a single. This should ensure energy savings while rotating from the heel (lower back) to the (sole) tip, see Figures 15 and 16.

DOCUMENTS REFERRED TO IN THE DESCRIPTION

This list of documents referred to by the author of the present patent application has been prepared solely for the reader's information. It is not an integral part of the European patent document. Notwithstanding careful preparation, the IEP assumes no responsibility for any errors or omissions.

Patent documents referenced in the disclosure of the disclosure of the disclosure of the patent, unless otherwise indicated. US Pat. Nos. 3,619,671 B,

Lisbon, January 8, 2015

Claims (13)

Gravitational footwear in the form of shoes or boots having a sole (3), with the energy accumulation caused by the elastic deformation, comprising a spring unit which comprises at least one flexing spring (1) of flexibility, from the initial state to a compressed state, and formed by elements, wherein the lower part of the spring (1) is a support element, intended to make contact with the support surface and the upper part of the spring (1) is disposed with fastening devices for securing a position of the user's foot and communicating the gravitational effect on a spring (1) of the spring unit, wherein the fastening devices for communicating the gravitational effect of the spring (1) to the interior of the unit comprise an element in the form of an elastic strip which connects the upper part of the spring to a rigid insole or other element which suspends the foot of the wearer, wherein simultaneously H1> g2; no load is applied to the spring (1) and H1 = H2 or H1 approaches H2 when a load is applied to the spring, where H1 is the distance between the ends of the spring (1), H2 is the distance from the top of the spring (1) to the lower part of the user's foot, wherein the bending spring (1) constitutes the basic footwear elements, and the lower spring support element (1) inside the spring unit is carried out in the form of a heel (2), the sole (3) is realized with the possibility of contacting the support surface when load is applied to the spring (1), in which, in the preparation for the next step, the foot is supported on the support surface not only on the spring (1), but also on the sole. Gravitational footwear according to claim 1, characterized in that the sole (3) of the gravitational shoes can be connected by the spring to impart an additional gravitational charge on it, H3 > H2 when no load is applied to the spring (1), where H3 is the distance from the top of the spring (foot suspension point) to a point of attachment of the sole, H1 = H2 = H3 and H1 or H3 approach H2 when the spring (1) is compressed. Gravitational footwear according to claim 1, characterized in that the spring unit comprises a plurality of springs (1), located at the back of the shoe, and on its sides or at the front of the shoe, wherein the heel support member may be made in one piece with all or several springs or as part of several springs, wherein the number of upper and lower springs may be different. Gravitational footwear according to claim 1, characterized in that the heel is located when the compressed spring is located in the heel zone (2) of the wearer. Gravitational footwear according to claim 1, characterized in that when the heel is compressed, the spring is located adjacent to the wearer's soles. Gravitational footwear according to claim 1, characterized in that the heel is adjacent to the sole and attached thereto. Gravitational footwear according to claim 1, characterized in that the spring has a simple arcuate shape (arched shape) or an arcuate shape provided with an additional curve, for example placed under the heel of the wearer; or semi-lipid shape (flattened), etc. Gravitational footwear according to claim 1, characterized in that the cross-section of the spring (1) is in the shape of a half moon, or in the form of a broad isosceles triangle, the flat ellipsoid shape or the rectangle shape in U. Gravitational footwear according to claim 1, characterized in that the cross-section and longitudinal section of the spring (1) can be constant or variable. Gravity footwear according to claim 1, characterized in that the spring material, its physical and technical properties are constant or variable in terms of length, width and thickness. Gravitational footwear according to claim 1, characterized in that the spring is made in part or in whole of one or more materials, such as polymers, including polyurethane, polycarbonate, etc., compounds, elastomers, etc. Gravity footwear according to claim 1, characterized in that the upper part of the shoe includes an insole which partially or completely covers the strap of the spring (1) or joins it, ensuring the possibility of changing the angle of the strap of the shoe (1), for example by performing the tops of a corrugated material or in the form of a lamina of coherent and extensible elements. Gravity footwear according to any preceding claim, characterized in that the spring is provided with a fastening device and a release device for securing a device by means of hooks, if necessary, for example, before the repulsion of the user's foot off the support surface. Lisbon, January 8, 2015