EA010661B1 - Heat-generating plate - Google Patents

Abstract

The invention relates to a heat-generating plate comprising adjacently arranged spring elements which generate frictional heat and can be displaced in relation to each other in a frictional manner under the effect of compression and decompression. The inventive plate is characterised in that two series (S1, S2) of spring elements, which are curved in a groove-type manner and produced from a spring-elastic material, are arranged between two parallel cover plates (21, 22). Said spring elements can expand under the effect of a compression (DB) and can return to the original groove shape thereof under the effect of a decompression (DE). They are also approximately in the form of strips, the convex surfaces (KXF) thereof being oriented towards one of the plates (21, 22) and the longitudinal edges (31) thereof being respectively oriented towards the other plate. Respectively two adjacent free longitudinal edges (31) of respectively two adjacently arranged spring elements (3, 3') of the two series (S1, S2) protrude into the concave region (KVR) of the spring elements of the other series and lie on the concave surfaces (KVF) thereof. In the event of a compression, the edges of the spring elements of one series can be displaced in a frictionally sliding manner against the concave surfaces of the spring elements of the other series, generating frictional heat, and in the event of a decompression, the spring elements return to the original groove shape thereof, simultaneously generating frictional heat.

Description

FIELD OF THE INVENTION

This invention relates to a heat generating plate, in particular a film with located therein, adjacent to each other by alternately applying or removing a compressive load, oscillatingly displaced relative to each other with friction and at the same time generating elastic heat generated by friction.

The problem of “cold feet” in the cold season is quite well-known, and there are a large number of different proposals for providing external supply of energy, giving off heat to the shoe soles, which, however, all have the disadvantage that when they are used, they need to be exhaustive after a short or long period of time, an energy source, such as a battery, battery or heat generator based on a thermochemical reaction.

From I8 4756095 A it became known a relatively complex, several-part mechanical device for heating the sole, which contains a rigidly fixed upper plate and, according to an embodiment, on the side of the toe of the shoe, the lower plate is in longitudinal and transverse frictional contact with the lower plate, and the lower plate by means of an indented separate spiral elastic element with a diagonal upward and backward directed and with a thrust shoulder diagonally upward and forward, as well as By means of a subsequent flat spring, it abuts in the zone of the sole in front of the foot and is held pressed to the rigidly fixed upper plate. The plates during the onset and release of the boot when walking in a friction state with each other are displaced relative to each other and thus generate the heat generated by friction for the desired warming of the sole and the inside of the boot.

The device for heating the soles described in I8-A has a very significant drawback in that it consists of several parts, of which at least the elastic elements and their installation in the sole of the shoe are relatively expensive, which led to the fact that this known the design has never been used in daily practice.

Further, a self-heating sole c became known from EK 1250059 A, due to the alternating load and unloading when walking, mainly moving back and forth relative to each other and at the same time plane rubbing against each other and thus generating heat generated by friction, shoulders and having an approximately plane-spiral cross-sectional shape with an elastic bracket.

A significant drawback of this well-known sole is that, due to the flat design of the elastic bracket, the sections of the path themselves, periodically changing the relative movement of the elastic shoulders relative to each other when applying and removing the compressive load when walking, are short and, what is more, only only a planar uniform application of compressive load during the attack, and the high initial loading of the sole through the heel of the shoe wearer during the attack cannot be used for vigorous long-term o lasting sequential attachment of the friction surfaces of the elastic shoulders. A significant drawback is, further, in the high stiffness of this type of self-heating soles caused by flat springs.

Shoe arch support is known from ΌΕ 1485802 A1, in which several layers of preferably different materials are laid on top of each other, preferably in the form of films in such a way that with the help of changing compressive stresses the parts lying, respectively, between two fixed layers, films or film combinations, in comparison with the fixed layers, deviating and relative movements are carried out across the direction of application of the load and, due to this, they generate heat generated by friction, and electrostatically th charge.

The present invention has set itself the task of creating a self-heating by applying or removing a compressive load, such as, for example, by using shoes, a plate or film, in particular, a sole or arch support, which practically does not differ in appearance and appearance from traditional soles of this type and moreover, to generate the desired heat there is a kind of friction generator of a simple design - working on the basis of friction adjacent to each other and pressed against each other by means of cally changing application and removal of a compressive load, in particular by means of distance and inversely shifting the friction surfaces of the friction plates or with a high efficiency in respect of heat generation.

It was found that the efficiency of heat generation through friction is especially high when there are prerequisites for a larger number of separate heat-generating elements proper, which are equipped so that at each step loading, mainly by dragging or sliding friction of these elements mutually generated heat.

The subject of this invention is a heat-generating plate or film with adjacent, adjacent to one another, displaced back and forth by alternately applying and removing a compressive load, rubbing against each other and oscillating relative to each other and generating heat generated by friction elastic elements, and a plate, in particular a film, characterized in that between two located mainly parallel to each other

- 1 010661 and adjacent plates or films connected to each other by their edges or edge zones, in particular between the cover plate and the base plate or film, are two series mainly located parallel to each other and at a distance from each other, next to each other approximately curved gutters made of an elastic material, when the compressive load is applied planely, they expand elastically or even out, and when the load is relieved, they return to their original gutter-shaped - in the aligned state it is mainly strip-shaped or approximately longitudinally rectangular in shape, directed by its concave surfaces, respectively, to one of the plates or films, and with both of their free longitudinal edges, respectively, to another plate or film, elastic elements, and, respectively, , two adjacent to each other free longitudinal edges, respectively, of two adjacent adjacent to each other and located at a distance from each other elastic elements of each of both series protrude inside of the space of elastic elements, respectively, of another series of elastic elements and are located snugly on their local concave surface, and that when a plane compressive load is applied or when the load is unloaded, at least the free edges of the elastic elements of one of both series are displaced, sliding with friction, on the concave surfaces of the elastic elements, respectively, of another series of elastic elements with the generation of heat generated by friction, while bending expansion or alignment, and that when mind The elastic elements are also reduced or with an increase in the plane compressive load, or when the load is removed, the elastic elements are also made to fit at least the free longitudinal edges of the elastic elements of one of both series to the concave surfaces of the elastic elements, respectively, of the other series, which return reversibly to their original trough-like shape , sliding with fit and friction, and also generating heat generated by friction and vice versa. The elastic elements can be made of any non-fatigue elastic material, in particular metal and / or synthetic material, and elastic elements of a uniform material, but also of two or, if necessary, a larger number of different materials can be provided in the new sole.

Particularly preferred is the embodiment of a new plate or film, according to claim 2, in the form of a sole.

The obvious advantage of the invention is that it is no longer necessary, as is necessary in all previously known proposals, to design a mechanically expensive and relatively space-consuming elastic mechanism in the sole of the shoe, and that it does not have to provide any specially designed voids for placement generating heat generated by friction, elastic mechanisms or something similar, which, for example, necessarily requires a heel, and that the soles, not as before, due to the relatively high need The tee in place for the elastic mechanism of the heat generator should be made shapelessly thick or rough, and for the first time at its disposal is an extremely flat, self-heating by kinematics when walking, flexible shoe sole, which with absolutely sufficient power generated by heating at winter temperatures from -10 ° C and lower may well have a material thickness of only 5 mm.

A further significant advantage of the self-heating plate and, accordingly, the shoe sole or arch support in accordance with the invention is that due to the large number of independently springing, respectively, self-springing, elastic flexible, groove-shaped, serving as friction heat generators, elastic elements , a plate or film in a direction perpendicular to the elongated elastic elements, i.e. in the longitudinal direction of the sole, despite the heat-generating structures, it usually remains elastic and flexible, and that a new plate or film, moreover, also in the direction of longitudinal extension of the elastic elements or perpendicular to the longitudinal direction of the sole, with a topographically different loading pattern, for example, given the sole of a person’s foot, can absolutely adapt in place relative to a given topography.

Along with the generation of heat, which represents a significant effect of the invention, by means of mechanics or kinematics of walking, another preferred effect is achieved, namely, a kind of pinching and soothing of the soles of the soles of the feet, which leads to the activation of blood supply to the feet by means of individually moving individual gutter-shaped elastic channels acting through the cover plate elements, and this stimulation of blood circulation additionally leads to the maintenance of the legs in a warm state.

In the basic form described so far, both longitudinal edges of the elastic elements of each of the two series are linear along the entire length and “slide”, respectively, almost along their entire length along the concave surfaces of the elastic elements, respectively, of the other series.

It was noted that during the change of load when walking near elastic elements with solid longitudinal edges, along with the generation of heat, the deformation of elastic elements is discontinuous, which manifests itself as a kind of click when the load changes. This circumstance, which, however, under certain conditions a consumer may consider burdensome, has one

- 2 010661 ko was found to be an unconditionally preferred side effect. The clicks have sound frequencies, which lead to the fact that sound energy penetrates deeper through the skin of the sole deeper into the tissue of the sole of the foot and there contributes to its activation, and as a result, improves blood circulation and, thereby, promotes its own heating of the foot from the inside, which is not only pleasantly perceived , but also, as practice shows, leads to the fact that by means of this stimulation of the tissue, the heating of the legs lasts surprisingly long also after the end of using the new sole.

In a series of studies on the creation of a self-heating “flat” sole, the use of which does not require this additional physiological heating effect, and further, if in essence very intermittent, already very muffled sole material, foot and shoe clicks were not found, it was found that the click effect just described is completely leveled if a multitude of cuts or strip-shaped recesses are made in the elastic elements, extending from their longitudinal edges, as can be concluded from claim 3 of the formula inventions.

Paragraphs 4-8 of the claims identify various preferred embodiments of the plate in its modified basic form according to claim 3.

As for the material of the base plate and the cover plate of the new plate, in particular, the sole of the shoe or instep, then, as can be concluded from paragraph 9 of the claims, when choosing a material, only the same framework is set here as when choosing a material for ordinary shoe soles or arch support. For example, shoe arch supports for adjacent plates or films can, of course, also use absolutely vapor-permeable, open or closed porous materials, as well as mesh or knitted materials.

In order that, in particular, it is valuable and favorable for shoe soles and arch supports, it is useless not to remove in the new sole the heat generated by periodically loaded and unloaded elastic elements generated by friction in the new sole, in those areas where it is not needed , then it may turn out to be advantageous to produce a cover plate, for example, of an improved thermal conductivity due to the inclusion of particles of carbon or a metal of a polymer, a leather substitute, or something similar, and to produce a base plate from por plain or foamed synthetic material, as it can be generally concluded from claim 10 of the claims.

The joining of the cover and base plates along their joint edges, as provided for in claim 11, is preferable in that it prevents lateral softening or outflow of elastic elements.

In terms of the stability of the geometric arrangement of the elastic elements of each of both series of elastic elements and the generation of heat as evenly as possible over a large area of the surface of the new plate, fixing the position of the elastic elements by attaching them to the covering and / or base plate, according to item 12, is an advantage, namely, in a convenient way, since this fixing, for example, by gluing, seam, riveting or something similar, passes mainly along the lines of the vertices, respectively, turned to to soles or covering plates, concave surfaces of gutter-shaped elastic elements.

In fact, elastic elements that are made of high-quality steel, i.e., for example, in the simplest case, of nichrome steel (chromium-nickel steel), as it can be concluded from claim 13 of the claims, have justified themselves in particular, since steel, with one the sides have high elastic elasticity and are not sensitive to humidity and the atmosphere prevailing in the boot.

With regard to shaping the cross section of approximately gutter shaped elastic elements, this section can correspond to the shape of a hyperbola, parabola, ellipse and, in particular, an arc of a circle, as can be concluded from paragraph 14 of the claims. The only important thing is that they do not have break points, i.e., for example, faults on a curve.

As already emphasized above, the present, not previously achieved by any self-heating plate, i.e., in particular, a shoe sole or instep, a significant advantage of the invention lies in the strikingly small total thickness of the new heat-generating plate, which, in particular, is important shoe soles and arch support for elegant fashionable shoes. Accordingly, specific dimensional data, i.e. data regarding approximation of the parameters of elastic elements close to practice are a feature of the invention, which brings significant advantages in claim 15.

If a new self-heating plate, in particular in the form of a film, for example, has to find application as an overlay for the driver and passenger seats in an off-road vehicle, where driving on uneven terrain leads to continuously changing loading and unloading of seat cushions and, thus , of a new lining plate or lining film, by means of the driver and passenger, the parameter ranges presented in paragraph 15 of the claims, of course, may well be exceeded.

In conclusion, it may still be envisaged to fill the space between the cover and base plates with a soft gel-like mass, as can be concluded from claim 16. In addition, it is important that it has practically no sliding effect or lubrication that significantly reduces the friction of the elastic elements relative to each other. Depending on the circumstances, the gel may be up to

- 3 010661 abrasive particles are added to increase friction.

Based on the drawings, the invention is explained in more detail.

In FIG. 1 shows an oblique view of a fragment of a plate in accordance with the invention having a contour of the sole-arch support. In FIG. 2 and 3 respectively show longitudinal sections of a self-heating sole according to the invention in an unloaded state, i.e. in the initial state, and in a state with a relatively high compressive load, as, for example, when advancing during walking. In FIG. 4 shows a special embodiment of one of the elastic elements of the new sole.

In FIG. 1 shows how in the space ΚΖ between two adjacent plates 2, in a particular case between a base plate 22 and a cover plate 21 of a self-heating plate 1 or sole 10, in accordance with the invention, there are two series 81, 82 of gutter-shaped, elongated elastic elements 3 and 3 ', and the elastic elements 3 of the first series 81 with their convex surfaces KXE are turned to the covering plate 21, and with their free longitudinal edges 31 are turned to the concave surface of the KUE elastic elements 3' of the second series 82 and, going into their vog the empty space of the CCC is adjoined there by its free longitudinal edges 31, as, on the contrary, alignment with the elastic elements 3 ′ of the second series 82 occurs. When loading the plate 1, for example, when the wearer of the shoe exposes the sole of the shoe to a flat compressive load ΌΒ, then the cover plate 21 approaches the base plate 22.

As spaced apart from each other at a distance parallel to each other and adjacent to each other, gutter-shaped, elastic elements 3 of the first series 81 turned by their convex surfaces KXE to the covering plate 21, and elastic elements 3 turned by their convex KXE surfaces to the base plate 22 'series 82 resiliently compressible ΌΒ and “expand”, i.e. their bending becomes smaller or the "radius" of their transverse bending becomes larger, and in the extreme case of a particularly large compressive load, it can even reach the "alignment" of the gutter-shaped elastic elements 3, 3 'of both series 81, 82.

During the process just described, the free longitudinal edges 31 of the elastic elements 3 of the first series 81 protruding into the concave spaces of the CCC of the elastic elements 3 ′ of the second series 82 “slide” along the concave surfaces of the CCC of the elastic elements 3 'of the second series 82, being pressed there more or less intensively with friction, respectively, in opposite directions relative to each other. At the same time, also under the influence of "extension" or possible alignment, the free edges 31 of the elastic elements 3 'of the second series 82 "slide" along the concave surfaces of the KUE elastic elements 3 of the first series 81 - there are also abutting under pressure - intensively with friction in opposite directions relative to each other and likewise also generate heat generated by friction.

When the load ΌΕ is removed, the elastic elements 3, 3 'again return to their original trough-like shape, and this, however less intensively, also leads to the described adjacent “sliding with friction” of the free longitudinal edges 31 of the elastic elements 3 of the first series 81 along the concave surfaces of the KUE elastic elements 3 'of the second series 82 and, conversely, alignment with the elastic elements 3' of the second series 82.

When sliding along the friction of the free longitudinal edges 31 of the elastic elements 3 of the first series 81 along the concave surfaces of the KUE of the second series 82 under a compressive load ΌΒ and, conversely, when the load ΌΕ is removed, the heat generated by friction is generated, which creates the prerequisites for heating the sole through mechanical movement under walking from the side of the person shod in the boot, and, as a result, to heat the boot and feet of the wearer of the shoe.

In FIG. 1 also explains how the new, self-heating due to the periodic compressive load ΌΒ and the removal of the load ΌΕ, the plate 1, approximately having the foot contour of the boot boot 10, the covering plate 21 is connected to the base plate 22 along their edges or edge zones 23, for example, by a seam 231, thereby preventing lateral exit of the elastic elements 3 and 3 'between the covering plate 21 and the base plate 22.

Further, using - here only - respectively, one thrust element 3, 3 'of series 81, 82, it is explained that the elastic elements 3 of the first series 81 along the lines of the vertices 81 of their convex surfaces KXE, for example, by gluing 5 or in another similar way, attached to the cover plate 21, and the elastic elements 3 'of the second series 82 are likewise connected to the base plate 22, thereby preventing the bi-directional displacement of the elastic elements 3, 3' relative to each other preventing the generation of heat generated by friction That is, for example, might meet with rolling the feet when walking.

It was found that, for example, to stabilize the position of the elastic elements 3, 3 'in the arch supports may be sufficient if only the elastic elements 3' of the second series 82 are stationary attached to the base plate 22.

Presented in FIG. 2, with the remaining constant designations and values, the longitudinal section view of a new self-heating plate, in particular, a shoe sole or instep 1, demonstrates it in a normal state not loaded with a plane load, i.e., in a state of unloading

- 4 010661 ki ΌΕ. This view clearly illustrates the relative position of spaced apart, pointing their free longitudinal edges 31 to the base film 22, and their convex surfaces KXE to the covering film 21, the elastic elements 3 of the first series of elastic elements 81 and, so to speak, respectively, located with offset half of the gutter - arcs of the gutter-shaped elastic element 3 'of the second series 82, and, as the elastic elements 3 of the first series 81, respectively, abut with their free edges 31 to the concave surfaces of the KUE of the elastic elements 3' Torah series, and vice versa. It is shown here that both the elastic elements 3 and the elastic elements 3 'are mainly attached along their vertex lines §1 to the base and to the covering films 22, 21. Further, short arrows in some places show how the free longitudinal edges 31 of each of the elastic elements 3 of the first series 81, sliding with fit, are moved away from each other along the concave surfaces of the KUE elastic elements 3 'of the second series 82, when it comes to the compressive load ΌΒ and vice versa.

FIG. 3 represents, with the remaining constant notation-values, a section of a similar plate 1 in a state under the influence of a compressive load ΌΒ. There you can clearly distinguish how all the elastic elements 3, 3 'now have essentially negligible bending, and to achieve this state with their free longitudinal edges 31 along the concave surfaces of the KUE, respectively, of two adjacent elastic elements 3', 3, respectively , of another series are shifted “gliding”, while generating heat generated by friction. The plate or sole 1 now has a significantly smaller thickness under the action of the compressive load, than without it, as shown in the already set out FIG. 2.

With the arrow pointing up to FIG. 2, the change in the new plate is indicated when the load сня is removed, and with this unloading ΌΕ, the initial state of the new plate or sole 1 unloaded from the force of force is again achieved, according to FIG. 2. Then all the elastic elements 3, 3 'again return to their original stronger bend. Even when the load ΌΕ is removed, the free edges 31 of the elastic elements 3, 3 'again slide back and to each other along the concave surfaces of the KUE elastic elements 3', 3, respectively, of another series and when the load ΌΕ is removed, by "sliding to each other", they also generate heat generated by friction, although less than during the onset or compressive load ΌΒ in a new self-heating plate or sole 1.

Presented in FIG. 4, the form of execution of the elastic elements 3, 3 '- though not changed in their original form with the location inside the sole and in the main function - has the advantage that these elements when changing the load while walking except - as it turned out - are not audible to the consumer and standing next to a person rustling friction inside the sole 1, do not produce any "clicks".

At the trough-like elastic element 3, strip-shaped recesses 33 extending from the edges 31 are cut, which, relative to the apex line §1, are located symmetrically to each other. According to FIG. 4, their length 1a is about a third of the length of the arc or the width b of the elastic element 3, so that a kind of continuous longitudinal bridge is preserved in the region of its apex. The width ba of the edge recesses 33 of the elastic element 3, according to this figure, is about a tenth of its own width bE. The indentations aa of these recesses 33 about each other correspond to about a fifth of the width of the elastic element bE

Claims (16)

CLAIM 1. A heat-generating device consisting of plates (21, 22) that are mainly parallel to each other and connected to each other by their edges or edge zones (23), and also between elastic elements (3) adjacent to each other, differing the fact that the elastic elements are two series of parallel, approximately grooved curved elements made of elastic plastic and / or metal material, directed by their concave surfaces (KXE), respectively, to one of the lasting (21, 22), and with its two free longitudinal edges (31), respectively, to another plate (22, 21), and, respectively, two adjacent free longitudinal edges (31), respectively, two adjacent each other and located at a distance from each other elastic elements (3, 3 ') of each of both series (81, 82) protrude inside the concave space (CLC) of elastic elements (3', 3), respectively, of the other series (82, 81) of elastic elements and, accordingly, are located with a fit on their local concave surfaces (KUE), and planar load or when removing the load (ΌΒ), at least the free edges (31) of elastic elements (3, 3 ') of one of both series (81, 82) are displaced, sliding with friction, over concave surfaces (CUE) of elastic elements (3 ', 3), respectively, of another series (82, 81) of elastic elements, generating heat. 2. Plate according to claim 1, characterized in that it is made in the form of a sole or instep (10) of shoes with the shape of the sole. 3. Plate in PP.1, 2, characterized in that at least part of preferably all elastic - 5 010661 gih elements (3) of at least one series (81, 82), preferably of both series (81, 82), have outgoing, respectively, from both their free longitudinal edges (31) located at a distance from each other, preferably straight-line, apexes extending in the direction of the line (§1), or oblong strip-shaped notches (33). 4. Plate according to claim 3, characterized in that the notches or recesses (33) of the gutter-shaped elastic elements (3) have between themselves the same appearance and / or length (b) and / or width (b), and their lengths ( 1a), respectively, range from one-tenth to a third of the width (L) of the elastic elements (3) or correspond to the length of the arc of the shape of their cross-section. 5. Plate according to claims 3, 4, characterized in that the notches or recesses (33) of the gutter-like elastic elements (3) have between themselves the same appearance and / or length (La) and / or width (La), and the widths (bа), respectively, are from the width of the usual cut in the steel material of the elastic element (3) maximum to the fifth part of the width (b) of the elastic elements (3) or the length of the arc of their cross-sectional shape. 6. Plate according to one of the claims 3 to 5, characterized in that the notches or recesses (33) are mainly located vertically from the free longitudinal edges (31) of the elastic elements (3) in the direction of their vertex line (§1). 7. Plate according to one of claims 3 to 6, characterized in that the bases of the recesses (33) and / or their transitions to the longitudinal edges (31) of the elastic elements (3) are rounded. 8. Plate according to one of the claims 3-7, characterized in that the notches or grooves (33) with respect to the line of the top (§1) of the elastic elements (3) are located opposite, symmetrically relative to each other. 9. Plate according to claims 1-8, characterized in that the covering and / or base plate or film (21, 22) is made using mutually similar or different, bending, flexible and / or elastic material, preferably from textile, felt, synthetic and / or leather material. 10. Plate according to one of the claims 1 to 9, characterized in that the covering plate or film (21) and / or the base plate (22) are made of heat-conducting material, such as, for example, a porous foam. 11. Plate according to one of claims 1 to 10, characterized in that the covering and base plates (21, 22) are connected to each other by their edges or edge zones (23) by means of gluing, seam (231). 12. Plate according to one of claims 1 to 11, characterized in that heat generated by friction, elastic elements (3, 3 ') between the covering and base plates (21, 22) of at least one of both series (81 , 82) mainly on or along the top line of their concave surfaces (KHP) are stabilized connected, respectively, with the covering and base plates (21, 22) located here, for example, by gluing, seam (5), riveting to their position inside plates (1), in particular the soles (10). 13. Plate according to one of the claims 1 to 12, characterized in that the elastic elements (3, 3 ′) that generate heat generated during friction are made of high-grade steel. 14. Plate according to one of claims 1 to 13, characterized in that the gutter-shaped elastic elements (3, 3 ') have a cross-section in the shape of an arc of a circle, parabola, hyperbola or ellipse. 15. Plate according to one of claims 1 to 14, characterized in that the gutter-shaped elastic elements (3, 3 ') have a bending radius in the range from 10 to 1.5 cm, in particular from 5 to 2 cm, or correspond to such kind of radius, and that when aligned, they are between 1 and 3 cm wide, in particular between 1, 2 and 2, 5 cm. 16. Plate according to one of claims 1 to 15, characterized in that the elastic elements (3, 3 ') are laid in the space ΚΖ between the two adjacent plates or edge zones (23) with adjacent plates (2), in particular , covering and base plates (21, 22), heat-conducting gel-like mass.