DE202018106335U1 - trampoline - Google Patents

Abstract

A trampoline comprising a jumping mat formed by movably connected lamellae forming a jumping surface of the jumping mat, wherein
the slats of the spring mat each have a slat body with at least two fastening openings and are movably connected to the fastening openings with further slats of the spring mat,
- The lamellae have a tread on a tread and the treads of the movably connected lamellae form the jump surface,
at least one of the lamellae has at least one receiving space in which at least one light element is arranged,
- The at least one light element comprises at least one generator for converting kinetic energy into electrical energy and at least one electrically connected to the generator light source, of which the generator is arranged and designed such that it in the case of a deflection of the spring mat electrical energy to the light source emits, so that the bulb emits light, and
- The lamp is arranged so that a lighting of the lamp is visible from outside the lamella.

Description

The invention relates to a trampoline, in particular for use as a game device, preferably on a playground, a jumping mat, preferably for a trampoline, and a lamella, in particular for a jumping mat.

Regularly trampolines are provided in various designs as playground equipment on playgrounds. Trampolines are often valued as play equipment, as they help people of all ages, and especially children, to exercise their sense of balance and body coordination. Also, when trampolining the whole body is stressed and demanded a high degree of concentration.

Trampolines typically have a jumping mat which is suspended in a steel frame, for example, by tension springs. On playgrounds trampolines are usually installed stationary. Here, the steel frame is mounted with the jump mat over a receiving space in the soil at ground level. The jump mat can be formed for example by elongated plastic slats. Such slats often have two bushings through which ropes, such as wire ropes, are passed. The slats of a spring mat are thus threaded on the ropes, so that the jump mats is characterized by a pattern of mutually offset lamellae. The ropes are thus perpendicular to the elongated bodies of the slats.

The slats are usually rigid in itself, so that the jump mat itself is movable only at the points where slats are connected to the bushings together. Typically, at the ends of such ropes loops are formed, on which the ropes, and thus the jump mat itself, is suspended by tension springs. The tension springs hold the jump mat in articulated storage and are connected to the steel frame. The spring action of the spring mat results in such embodiments, for a large part of the elastic properties of the tension springs. Here it is desirable that a trampoline used in a playground has the best possible trampoline effect and at the same time is robust, low-maintenance and safe. In particular, it is desirable that a trampoline installed in a playground stimulates children's urge to move. In order to direct the interest of persons on a trampoline, for example, motifs incorporated in the jumping mat can be used or a trampoline arrangement can be assembled from a plurality of trampoline modules.

It is an object of the invention to provide an alternative trampoline, an alternative jumping mat for a trampoline and an alternative blade for a jumping mat.

According to the invention this object is achieved by a trampoline comprising a jumping mat, which is formed by movably connected lamellae, which form a jumping surface of the jump mat. The lamellae of the spring mat each have a lamellar body with at least two attachment openings and are movably connected to the attachment openings with further lamellae of the jump mat. The slats have a tread on one side of the step. The treads of the movably connected lamellae form the jumping surface. At least one of the lamellae of the spring mat has at least one receiving space in which at least one light element is arranged. The at least one light element comprises at least one generator for converting kinetic energy into electrical energy and at least one light source electrically connected to the generator. The generator is arranged and designed such that it emits electrical energy to the light source in the event of a deflection of the spring mat, so that the light source emits light. The light source is arranged so that a lighting of the light source is visible from outside the lamella.

The light element is thus arranged in the receiving space and the lamellar body is formed so that the light source, when it is supplied by the generator with electrical energy, emits light that is visible from outside the lamella, in particular for a user of the trampoline.

In the context of this description, the jump surface of the jumping mat is the surface on which a user of the trampoline stands or jumps. The jump surface is formed by the treads of the individual slats of the jump mat. Accordingly, the side of the lamella called that side of the lamella on which the tread is located.

The jump mat is movable at least at the points at which slats are connected to the mounting holes movable with other slats of the jump mat.

Slats of a jumping mat are typically used to provide a tread for a user.

The invention includes the recognition that a lamella of the spring mat is suitable for realizing further functions.

In particular, the invention includes the recognition that a lamella is adapted to receive functional units and / or to gain energy, eg to house a generator in order to obtain energy. This includes the realization that the lamellae of a jumping mat are supplied with kinetic energy when used. This added kinetic energy can be harnessed by a generator.

The inventors have further recognized that the lamellar body of a lamella offers a design freedom which allows at least one receiving space to be arranged in the lamellar body. According to the invention, a generator is arranged in the at least one receiving space and is configured to convert at least a portion of supplied kinetic energy into electrical energy. The supplied kinetic energy is thus converted by the generator directly into a corresponding lamella into electrical energy.

The energy generated by the generator can then be used to power electrical components via electrical lines. According to the invention, the generator is electrically connected to a light source which emits light in the generator mode. The kinetic energy supplied by a user by jumping on the spring mat is thus advantageously first converted by a generator into electrical energy and the generated electrical energy is in turn converted by a light source into visible light. The light source is arranged so that emitted light is visible from outside the fin, so that a user can perceive the light while jumping on the spring mat. Thus, when a user jumps on a spring mat, which has a lamella with a light element, the generator of the light element is advantageously driven by the vibration of the spring mat and the light source is excited to shine. This can increase the appeal and play value of a trampoline and encourage a user to jump on the trampoline. A user can change or adapt his jumping behavior on the trampoline, for example, according to the light effect generated.

The application of kinetic energy to a lamella, the conversion of the supplied kinetic energy into electrical energy by a generator and the conversion of the electrical energy into visible light by a light source, jointly effect the effect that a user of a trampoline by the generated light effect an optical Receive feedback on his physical deployment.

Particularly advantageous embodiments of the trampoline according to the invention are described below.

The trampoline according to the invention is particularly suitable to be used as a game device in a playground. It is also suitable as a fitness or sports device, for example in a gym.

In a particularly preferred embodiment of the trampoline, the at least one generator comprises a coil and a permanent magnet. The coil of the generator is arranged with respect to the tread of the blade, that the longitudinal axis of the coil is perpendicular to the tread of the blade. The permanent magnet is movably disposed inside the coil along the longitudinal axis of the coil such that when the spring mat is deflected, the permanent magnet disposed inside the coil moves along the longitudinal axis of the coil and perpendicular to the tread of the fin. The movably arranged inside the coil permanent magnet can thus move relative to the lamella and performs due to its inertia actually a relative movement with respect to the lamella and in particular with respect to the coil of the generator, if the lamella, for example, by jumping children or generally restoring elastic forces is accelerated. By the vertical arrangement of the coil with respect to the tread surface is exploited that the transmitted by a jump of a user on the spring mat pulse in the jump direction, i. perpendicular to the tread, is the largest. That is, by supplied kinetic energy, the deflection of the spring mat and thus the individual slats in the jump direction is greatest.

The coil is preferably a wire coil whose wire is wound at a distance about the longitudinal axis of the coil. The coil is preferably an air coil, that is, the coil wire is not wound around a solid core, but inside the coil, a hollow cylindrical coil cavity is formed. The coil may be cantilevered or formed by a coil-wound non-magnetic coil support. The coil of the generator is preferably arranged with respect to the tread of the blade, that the longitudinal axis of the coil is perpendicular to the tread surface. That is, the base of a cylindrical coil is arranged parallel to the tread surface.

Preferably, a permanent magnet is movably arranged along the longitudinal axis of the coil in the coil cavity formed in the interior of the coil. That is, when kinetic energy is supplied to the generator, the permanent magnet can move along the longitudinal axis through the interior of the Move the spool back and forth. Due to its inertia in its reciprocating motion, the permanent magnet follows in particular a movement of the lamella in which the light element is arranged with the generator. Thus, when a user jumps on a jumping mat of a trampoline having such a louver with light element, the kinetic energy supplied by the user can be at least partially absorbed by the permanent magnet in the coil. The permanent magnet in turn performs a linear movement along the longitudinal axis of the coil. By moving the permanent magnet inside the coil, the magnetic flux density changes locally for the coil, thereby inducing an electrical voltage in the coil according to the principle of electromagnetic induction. The generator with coil and permanent magnet described here thus functions as a linear generator, which converts the kinetic energy of the rectilinearly moving permanent magnet into electrical energy.

According to the invention the object mentioned is achieved by a jumping mat, which is formed by movably interconnected slats, wherein the slats form a step surface of the jump mat. The lamellae of the spring mat each have a lamellar body with at least two attachment openings and are movably connected to the attachment openings with further lamellae of the jump mat. The lamellae have a tread on a tread surface and the treads of the movably connected lamellae form the jumping surface. At least one of the lamellae has at least one receiving space in which at least one light element is arranged.

The light element comprises at least one generator for converting kinetic energy into electrical energy and at least one light source electrically connected to the generator. The generator is arranged and designed such that it emits electrical energy to the light source in the event of a deflection of the spring mat, so that the light source emits light. The light source is arranged so that a lighting of the light source is visible from outside the lamella.

The jumping mat according to the invention can be used particularly advantageously as part of a game device for a playground. The jumping mat according to the invention can also be used in the indoor area, for example as part of a fitness or sports equipment in a gym or as part of a game device of an indoor playground. Particularly preferably, the spring mat according to the invention is part of the trampoline according to the invention.

When a user jumps on the spring mat, the generator can pick up at least a portion of the kinetic energy supplied by a user and convert it into electrical energy. The electrical energy generated by the generator is then transmitted to the light source and converted by the light source into visible light. Advantageously, the lighting means is arranged so that the light emitted by the light source is visible from outside, in particular for a user of the spring mat. The emitted light can then be perceived by a user of the jumping mat while jumping on the jumping mat. The deflection of the spring mat, the driving of the generator and the emission of light in combination with each other, for example, give a user different optical feedback for different jumps.

Particularly advantageous embodiments of the jump mat according to the invention are described below.

In a particularly preferred embodiment of the spring mat, the at least one generator comprises a coil and a permanent magnet. The coil of the generator is arranged with respect to the tread of the blade, that the longitudinal axis of the coil is perpendicular to the tread of the blade. The permanent magnet is movably disposed inside the coil along the longitudinal axis of the coil such that when the spring mat is deflected, the permanent magnet disposed inside the coil moves along the longitudinal axis of the coil and perpendicular to the tread of the fin.

In a jump contact, in particular after a user has rejected the jumping mat, the added kinetic energy typically propagates wavy starting from the point of the jump contact in the direction of the edge of the jumping mat. If a jumping mat has several lamellae with integrated light element, this can lead to an optical wave effect, i. E. The light sources of the individual slats are stimulated to light up with a time difference. This lighting effect can add to the attractiveness of the trampoline as a sports device.

In a variant, the lamellar bodies of the lamellae have the same color. In a further variant, the lamellar bodies of the lamellae are transparent. If a motif is shaped by a targeted arrangement of lamellae with light elements in a spring mat, such as a rocket or a skull or the like, this motif is only by the addition of kinetic energy, i. by jumping on the spring mat, visible.

According to the invention, the object mentioned at the outset is achieved by a lamella which has a lamellar body with at least two fastening openings and has a tread surface on a tread side. The lamella has at least one receiving space in which at least one light element is arranged. The at least one light element comprises at least one generator for converting kinetic energy into electrical energy and at least one light source electrically connected to the generator. The generator is arranged and designed such that it converts supplied kinetic energy into electrical energy and emits the electrical energy to the light source, so that the light source emits light. The light-emitting means is arranged and the lamellar body designed accordingly that a lighting of the light source is visible from outside the lamella.

The blade according to the invention is particularly advantageous part of the jump mat of the trampoline invention or the jumping mat according to the invention. However, the blade according to the invention can also be used as part of another game or fitness device. Particularly advantageously, the blade is used in such a way as part of a device that the blade when using the device kinetic energy can be supplied. The lamella is thus advantageously a component of a movable element of a device, for example a jumping mat.

The generator is adapted to receive at least a portion of the energy supplied to the blade and to convert it into electrical energy. The electrical energy generated by the generator is then delivered to the bulb and converted by the bulb into visible light. The luminous means is arranged such that light emitted by the luminous means can be perceived from outside and in particular from a user who supplies kinetic energy to the generator.

Particularly advantageous embodiments of the blade according to the invention are described below.

In one embodiment, the receiving space is open at least on one side to the outside. The light element arranged in the outer space is preferably accessible through the opening from the outside. The opening is preferably formed in an outer surface and in particular in the tread surface. The receiving space then extends from the opening formed in the outer surface of the slat body into the slat body. Preferably, the opening is dimensioned such that the light element can be removed through the opening from the receiving space.

Preferably, the opening is formed in the tread surface light exit opening. The light element is then arranged in particular in the receiving space such that the light source, when it is supplied by the generator with electrical energy, emits light in the direction of the tread side of the lamella through the light exit opening formed in the tread surface. If the slat is a slat of a jumping mat, a user of the jump mat can directly perceive the light emitted through the light exit opening.

The opening may also be a light exit opening which is formed in an outer surface of the lamellar body opposite the tread surface. The light element is then preferably arranged in the receiving space such that the light source, when it is supplied with electrical energy from the generator, emits light in the direction of the side of the lamella opposite the tread side through the light exit opening formed in the outer surface. If such a slat is part of a jump mat, a user of the jump mat can indirectly perceive the light emitted by the light exit opening, for example by illuminating a cavity under the jump mat.

In one embodiment variant, the light element is cast in the lamellar body and completely enclosed by the lamellar body. The disk body then preferably has no opening. The material of the laminar body is then preferably at least partially transparent.

The lamellar body preferably has an elongate shape. But it is also conceivable that the lamellar body has a round or cylindrical, in particular disk-shaped form.

An elongate lamellar body preferably has a length of between 5 and 16 centimeters, a width that is between 1 and 7 centimeters and a depth that is between 1 and 7 centimeters. It may be advantageous if the width and depth of a fin body are substantially identical. In some embodiments, it may also be advantageous if the width and depth of a disk body differ from each other. For example, a width of 5 to 7 inches and a depth of 2 to 3 inches. For example, it may be advantageous to increase the tread surface of a fin body by choosing a comparatively large width. The depth can still be chosen comparatively small, so as not to unnecessarily increase the weight of the lamella.

With respect to the tread of the blade can be particularly advantageous symmetry planes of the Defining lamellar body: The lamellar body is preferably symmetrical to the vertical longitudinal plane which is perpendicular to the tread of the lamella. Longitudinal planes are the planes that comprise the longitudinal axis of the lamellar body.

At each of the two longitudinal ends of the elongate plate body is preferably one of the two mounting holes. Preferably, the attachment openings are aligned parallel to each other and extend in a horizontal longitudinal plane, wherein the horizontal longitudinal plane is aligned parallel to the tread surface. Preferably, the attachment openings in the horizontal longitudinal plane are arranged symmetrically along the height of the lamellar body, i. the distances from a mounting opening to the tread of the lamella and to the side opposite the tread surface of the lamellar body are the same.

The lamellar body is furthermore preferably symmetrical with respect to a transverse plane which runs parallel to the cross-sectional surface of the lamellar body and exactly in the middle between two fastening openings arranged at the longitudinal ends of the lamellar body. This transverse plane is thus aligned perpendicular to the jump surface of a jumping mat and runs exactly perpendicular to the horizontal and to the vertical longitudinal plane.

With lamellae, which have the above-mentioned symmetry properties, a jump mat for a trampoline can be produced particularly easily and quickly. Furthermore, such slats are relatively robust and thus comparatively durable even with regular use in a game device.

Since the electrical energy for exciting a light source is generated by the generator, it is advantageously not necessary to integrate in the light element a battery or a rechargeable battery, which would have to be replaced or recharged after a certain time.

The light-emitting means preferably comprises a light-emitting diode (LED). Here, LEDs may be provided which emit white or green or blue or red light or light in a different color of the visible spectrum. An LED of the light source can be manufactured in different LED designs, for example as an LED module with multiple LEDs on a board or as a flexible LED strip. Advantageously, an RGB LED can be used, which is formed by a LED module with a red, green and blue LED. The light emitted by an RGB LED can be perceived by one observer as white light or as another color, depending on the mixture of light emitted by each LED. For example, light can be produced in a specific mixed color by targeted activation of the individual LEDs.

However, the luminous means may also comprise an SMD (surface-mounted device) LED or a COB (chip on board) LED.

Preferably, the light element is enclosed in the receiving space with a transparent potting material, so that the light element is encapsulated waterproof and the light emitted by the light source can be transmitted through the potting material.

The lamellar body may be formed by a bright, translucent material, so that a lighting of the bulb is visible from outside the lamella. The material can also be transparent only to the extent that light is scattered in the material in such a way that the light element itself is not visible from the outside or only dimly recognizable. At first, a lamella made of such a material is not seen to house a light element with a generator and a luminous means. Only when the lamella and in particular the generator kinetic energy is supplied and this converts it into electrical energy and transmits to the light source, recognizes a user on the basis of the light emitted from the light element that the lamella has a light element. The light effect, then occurs to a user comparatively surprising.

The at least one generator may comprise a coil and a permanent magnet. The permanent magnet is then preferably arranged inside the coil movably along the longitudinal axis of the coil and induces a voltage in the coil by moving along the longitudinal axis inside the coil by means of electromagnetic induction. The permanent magnet moves in a straight line along the longitudinal axis inside the coil. As a result, a linear generator is advantageously realized. The movement of the permanent magnet in particular follows the movement of the blade. By supplying kinetic energy, for example by a jump contact of a user on a spring mat, the permanent magnet inside the coil usually performs a damped oscillation. The permanent magnet thus moves inside the coil along the longitudinal axis back and forth until it reaches a rest position again. As a result, illuminates the bulb for the duration of the damped oscillation.

Preferably, the generator with the coil and the permanent magnet arranged in the interior of the coil is arranged in the at least one receiving space, the lamellar body such that the longitudinal axis of the coil is perpendicular to the tread surface of the lamella body and the permanent magnet is arranged perpendicular to the tread of the lamellar body along the longitudinal axis of the coil in the interior of the coil so that the permanent magnet, by supplying kinetic energy, perpendicular to the tread surface along the longitudinal axis the coil moves inside the coil. With a jump on a jumping mat, a user generates an impulse, which is transmitted to the jumping mat and deflected out of its resting position. The impulse override is greatest here in the jump direction, ie perpendicular to the jump surface. A lamella as part of the spring mat thus experiences an impulse which is greatest in the direction perpendicular to the tread surface. Thus, if the generator with a light element is arranged in the receiving space of a lamella such that the longitudinal axis of the coil is perpendicular to the tread surface, the permanent magnet moves back and forth by supplying kinetic energy in the direction of the largest momentum transfer. The generator is thus aligned in the receiving space of the lamellar body, that the possible momentum transfer to the generator by supplying kinetic energy in a direction perpendicular to the tread surface is greatest.

Preferably, the permanent magnet is made of the alloy neodymium-iron-boron. This alloy is characterized by the fact that it can be used to generate particularly strong permanent magnetic fields. Such permanent magnets can therefore be dimensioned comparatively small in order to produce a certain magnetic field strength. However, the permanent magnet may also have other alloys such as cobalt samarium, AINiCo, hard ferrites based on barium, strontium, PtCo, CuNiFe, CuNiCo, FeCoCr, martensitic steel or MnAIC.

The at least one light element may also have a capacitor electrically connected to the at least one generator and the at least one light-emitting means for storing electrical energy generated by the generator and outputting the stored energy to the at least one light-emitting means. Through a capacitor, electrical energy can be stored temporarily and distributed over a period of time to the light source. The period of time in which the luminous means emits light can thus be extended with respect to the duration in which a light element without condenser emits light.

If the lamellar body has a light exit opening, from which the receiving space extends into the lamellar body, it can be advantageous if the light exit opening is dimensioned such that a light element can be inserted through the light exit opening into the receiving space and removed from the receiving space. If the light exit opening is arranged in the tread of a lamella, such a light element can be easily replaced from the tread side, even if the lamella is installed, for example, as part of a trampoline in a spring mat.

The lamellar body may have at least one light exit opening formed in the tread surface and at least one further opening formed on the side opposite the tread side. In this embodiment variant, the at least one receiving space preferably extends through the lamellar body from the light exit opening to the opening of the lamellar body formed on the side opposite the tread side. The receiving space is thus accessible from the tread side and the side opposite the tread side. The light exit opening is preferably smaller than the opening formed on the side of the lamellar body opposite the tread side. Advantageously, a light element arranged in the receiving space is thereby difficult to access from the tread side for a user.

In one embodiment, the light exit opening and the opening formed on the opposite side of the lamellar body are designed such that the light element can only be removed from the receiving space by the opening of the lamellar body formed on the side opposite the tread side. Thus, if a lamella is part of a jumping mat, a light element can only be inserted or removed from the side opposite the jumping surface. This makes it difficult for a user to remove a light element from an already mounted jump mat.

The at least two attachment openings of the lamellar body are preferably formed by passage openings guided parallel to the tread surface and through the lamella body. Preferably, one of the feedthrough openings are arranged at each of the two longitudinal ends of a slatted longitudinal body. The passage openings preferably run parallel to one another. At each longitudinal end of the disk body so a passage opening is formed. The passage openings are preferably aligned parallel to each other and extend in a horizontal longitudinal plane which is aligned parallel to the tread surface of the lamella. At the feedthrough openings, fins can be made by passing a rope, e.g. a wire rope or a rubber rope, be connected to other slats, so as to produce a spring mat.

The lamellar body of the lamella preferably consists of plastic, for example polyamide, polypropylene, polyethylene or elastomers, or of Metal, for example aluminum, or wood. Plastic slats can be produced particularly advantageously in the 3D printing process. Plastic laminations are advantageously comparatively UV and temperature resistant and thus relatively robust and durable.

The lamellar body of the lamella is preferably rigid in itself. A spring mat formed of rigid lamellae is movable only in those places where the lamellae are movably connected. Rigid fins also result in a comparatively pronounced trampoline effect.

The at least one light element may have exactly one generator and a plurality of lighting means electrically connected to the generator, so that a plurality of lighting means are supplied together with electrical energy generated by the exactly one generator in generator operation. In order to increase the luminous efficacy per light element, it may be advantageous to supply a plurality of luminous means with electricity generated by a single generator.

In a preferred embodiment, the lamellar body has an elongated shape and the tread surface of the lamella has in a region of the tread surface a lateral broadening formed with respect to the elongate lamellar body. The tread of such a blade is thus enlarged. If a slat with a widening of the tread is part of a spring mat, the jump surface is enlarged at this point. As a result, the surefootedness of a user and thus the control during a jump contact can be increased. In addition, dirt or small parts, such as Key less likely to fall through gaps in a jumping mat due to the widening of the tread. Such a spring mat must therefore be less often dismantled to clean the cavity under the jump mat or to bring out small parts. Advantageously, it also results from widening a tread surface that a motif incorporated into the jumping mat acts more succinctly by closing gaps in the spring mat.

Preferably, the at least two attachment openings are arranged in each case at the two longitudinal ends of the slatted longitudinal body. The region of the lateral widening of the tread surface is then preferably located between the fastening openings arranged at the longitudinal ends. At the points where the lamella is to be connected to other lamellae, so the tread is preferably not widened.

It may be advantageous if the tread surface of the lamellar body has a structuring for increasing the slip resistance. Such structuring can be realized, for example, by a nubbed GRIPTEQ® surface, which allows a better grip.

Preferably, the light element is potted in the receiving space with a potting material. In particular, if a light element arranged in the receiving space is not potted, it may be advantageous to close an opening of the lamella body with a diffusing screen. In one embodiment, therefore, a formed in the tread light exit opening is closed by a lens. The diffusing screen is preferably designed to scatter light emitted by the illuminant in the direction of the light exit opening. As a result, the generated light effect can be amplified. The light emitted by the light source can therefore be better perceived by a user. Due to the diffuser, the light exit opening can also be complete, i. flat, be illuminated, which in turn can make the emitted light for a user more perceptible. Preferably, the diffusing screen is formed of a colored translucent material, so that the light emitted by the illuminant light is perceived by a user in a particular color. The use of different colored lenses is particularly interesting when a motif is to be incorporated into a spring mat by lamellae with light elements.

Preferably, the lens has a material with fluorescent properties. This emits light even after the material has been optically excited by the material having fluorescent properties for a typically very short period of time. The light effect can thereby be better perceived by a user since light is emitted for a comparatively longer period of time.

In one embodiment, a lamella has a lamellar body with at least two receiving spaces. In a variant, the receiving spaces are separated by a wall of the lamella body. In a further variant, the at least two receiving spaces are interconnected, i. h., The interconnected receiving spaces form a common, enlarged receiving space.

The lamella can have exactly three receiving spaces, in each of which a light element is arranged. Each of the light elements preferably comprises a generator and two light-emitting diodes which can be energized by the generator. The receiving spaces can be separated from one another by a wall of the lamellar body or else connected to one another. Preferably, each of the three receiving spaces extends from one each Light exit opening starting in the lamellar body inside. The disk body therefore preferably has three light exit openings. Each of the light exit openings preferably has a diameter of approximately seven millimeters. Preferably, the lamellar body on the side opposite the tread side has three openings, so that each of the receiving spaces extends between one of the openings and an opposite light exit opening. Preferably, a light element can be removed from one of the receiving spaces only by an opening formed on the side opposite the tread side and not by a light exit opening formed in the tread surface. Because of the plurality of LEDs, it is particularly advantageous to emit a quantity of light per slat, which is comparatively easily perceptible by a user.

In one embodiment, in which the lamella has a lamellar body with at least two interconnected receiving spaces, a light element may be arranged such that at least one generator of the light element in the one receiving space and at least one electrically connected to the generator light source is in another receiving space ,

The lamella can also have an elongated lamellar body with exactly three interconnected receiving spaces, which are arranged along the longitudinal direction of the elongated lamellar body. Two light elements are preferably arranged in the receiving spaces such that a light source of one of the light elements in the central receiving space and a generator of the corresponding light element electrically connected to a light source are located in a further receiving space adjoining the central receiving space.

In particular, a light element can extend over three interconnected receiving spaces and have two generators which are each electrically conductively connected to two LEDs. The total of four LED's are then preferably arranged in the middle of three interconnected receiving spaces and each one generator in one of the adjacent receiving spaces. The lamellar body then preferably has a light exit opening adjacent to the tread surface and to the middle receiving space. The light exit opening preferably has a diameter of approximately 12 millimeters.

In some embodiments, each one of two light elements is inserted in one of the two outer of three interconnected receiving spaces. Each of the two light elements preferably has a generator which is electrically conductively connected to two light sources. The two light elements can also be separated from each other by an additionally inserted partition and at the same time fixed by the partition wall in the corresponding receiving space. The two light sources of a light element are preferably arranged such that the generator is located between them. When the two light elements are inserted into the receiving spaces of the lamellar body, the four lamps in total are preferably arranged at regular intervals along the elongate lamellar body. In the tread surface of the fin body then preferably four light exit openings are formed with a diameter of preferably seven millimeters, each associated with exactly one of the four bulbs and arranged such that emitted light from the associated light source can be emitted through the corresponding light exit opening.

When a fin body has three interconnected receiving spaces, the fin body on the tread side opposite side preferably has an opening which extends over the three interconnected receiving spaces and can be removed by the one or more light elements from the receiving spaces.

A lamella having an opening formed on the side of the lamellar body opposite the tread side preferably has a closure element. The closure element is then preferably attached to the lamellar body of the lamella such that a light element is closed in a receiving space.

The lamella can also have at least one receiving space in which a plurality of light elements are arranged. It may be advantageous to make a receiving space so large that multiple light elements can be arranged in this. In particular, it may be that such a lamella can be manufactured with less effort compared to lamellae with several separate receiving spaces. A comparatively large receiving space can also be realized in that a plurality of receiving spaces are connected to one another and thus form an enlarged receiving space.

At least one light element can also comprise exactly one generator and exactly one light source. Such a light element represents a particularly simple form of a light element according to a concept of the invention. The production of a light element with exactly one generator and exactly one light source is also associated with a comparatively low production cost.

A light element may also have a housing, which is arranged in the at least one receiving space of the lamella, and which houses the generator and the lighting means. The housing is then preferably made of a transparent material. Advantageously, the housing protects the generator and the lamp from external influences. Preferably, the housing has the shape of a counterpart for a receiving space of a lamella, so that the light element with housing can be accurately inserted into the receiving space.

At least one light element can also be cast in the receiving space. By pouring the light element is fixed in the receiving space of a blade and at the same time protected against external influences. Only a permanent magnet in the interior of a coil is preferably not limited by the casting in its movement in the interior of the coil. Therefore, it is advantageous to shed a light element with housing in the receiving space, so that the generator and the lamp do not come into contact with the material used for casting. It is also conceivable that only the open sides of a bobbin are closed with a lid, so that a potting material can not penetrate into the bobbin interior. Preferably, a material is used for potting, which is transparent to the light emitted by the light element. By pouring the light element is advantageously sealed waterproof and in particular comparatively low maintenance. In addition or as an alternative to casting, the at least one light element can be glued in the receiving space.

At least one light element may also comprise a damping element for acoustically damping the generator. The damping element may, for example, be made of a damping material, e.g. a foam, be formed. The damping element may also have two magnets, wherein the one magnet near the tread side in the receiving space and the other near the side opposite the tread side are arranged in the receiving space with respective different magnetic poles to each other and the generator is disposed between the two magnets. For example, if the generator has a coil and a permanent magnet, and the permanent magnet inside the coil is freely movable along the longitudinal axis of the coil, magnets may be disposed above and below the coil such that the north pole of the permanent magnet faces the north pole of the one magnet and the south pole of the permanent magnet hits the south pole of the other magnet. As a result, the permanent magnet and the magnets mounted correspondingly above and below the coil repel each other without any mechanical contact with the magnets during a reciprocation of the permanent magnet. The permanent magnet is thus damped by the magnetic interaction with the magnets arranged above and below the coil.

Optionally, a lamella can have a closure element. The closure element is then preferably arranged on an outer surface of the lamellar body such that the opening to the receiving space of the lamellar body is closed by the closure element. By the closure element, a light element arranged in the receiving space can be protected against being removed or against external environmental influences. Preferably, the closure element is connected by a screw or an adhesive connection or by a cast connection fixed to the fin body.

A closure element may in turn also have at least one receiving space, so that a light element, when the closure element is attached to the lamella body, is located with a part in the receiving space of the closure element and with the remaining part in the receiving space of the lamella body.

At least part of the lamellae of the spring mat of the trampoline according to the invention or of the spring mat according to the invention can be designed according to at least one of the previously described refinements and variants of the lamella according to the invention.

• 1:schematisch ein Trampolin mit einer Sprungmatte;
• 2:eine von Lamellen gebildete Sprungmatte;
• 3:eine Lamelle mit einem Lamellenkörper, der einen Aufnahmeraum aufweist, in dem ein Lichtelement angeordnet ist;
• 4:eine Lamelle mit einem Lamellenkörper der drei Aufnahmeräume aufweist, in denen jeweils ein Lichtelement angeordnet ist;
• 5:eine Lamelle mit einem Lamellenkörper, der drei Lichtaustrittsöffnungen und drei auf der der Trittseite gegenüberliegenden Seite ausgebildete Öffnungen aufweist, wobei sich zwischen den jeweiligen Öffnungen ein Aufnahmeraum durch den Lamellenkörper erstreckt, in dem ein Lichtelement angeordnet ist;
• 6:eine Draufsicht auf eine Lamelle mit einer Verbreiterung der Trittfläche;
• 7:eine Schaltung für ein Lichtelement mit einem Generator und zwei Leuchtdioden;
• 8:eine Lamelle mit einem Lamellenkörper der einen Aufnahmeraum umfasst;
• 9:eine Lamelle mit einem Lamellenkörper, der drei miteinander verbundene Aufnahmeräume umfasst;
• 10a): eine Draufsicht auf ein Lichtelement;
• 10b): eine Seitenansicht des in 10a) gezeigten Lichtelements;
• 11a) eine Draufsicht auf ein Lichtelement;
• 11b) eine Seitenansicht des in 11a) gezeigten Lichtelements.

The invention will now be explained in more detail with reference to an embodiment with reference to the figures. From the figures shows

• 1 schematically a trampoline with a spring mat;
• 2 a jumping mat formed by slats;
• 3 a fin having a fin body having a receiving space in which a light element is disposed;
• 4 a lamella having a lamellar body of the three receiving spaces, in each of which a light element is arranged;
• 5 a lamella having a lamellar body which has three light exit openings and three openings formed on the side opposite the tread side, wherein between the respective openings a reception space extends through the lamellar body, in which a light element is arranged;
• 6 a plan view of a lamella with a widening of the tread surface;
• 7 a circuit for a light element with a generator and two light-emitting diodes;
• 8th a blade having a fin body comprising a receiving space;
• 9 a fin having a fin body comprising three interconnected receptacles;
• 10a) a plan view of a light element;
• 10b) : a side view of the in 10a) shown light element;
• 11a) a plan view of a light element;
• 11b) a side view of the in 11a) shown light element.

1 schematically shows a trampoline 100 with a spring mat 102 , The shown trampoline 100 is particularly suitable for use as a game device in a playground. In the embodiment shown, the trampoline 100 a rectangular shape. In various embodiments not shown here, a trampoline has a round or a rectangular shape deviating from the shown rectangular shape or another polygonal shape. The shown trampoline 100 is also suitable for use as a module in a trampoline arrangement.

The trampoline 100 includes a jumping mat 102 the movably connected lamellae 104 is formed, with the slats 104 a jumping surface 106 the spring mat 102 form. The slats 104 each have an elongated lamellar body and have on a tread side a tread surface. The treads of the movably connected lamellae 104 form the jumping surface 106 the spring mat 102 , In an embodiment not shown here, the lamellar body has no elongated but a different shape. Instead of an elongated lamellar body, for example, round or cylindrical, in particular disk-shaped lamellar bodies can be used to form a spring mat.

Each of the slats 104 has two mounting holes (not shown) through which a wire rope 108 is guided so that the slats 104 on wire ropes 108 are threaded. In an embodiment not shown here, the slats are on elastically stretchy ropes, z. B. threaded rubber ropes. The slats 104 are so on the ropes 108 Threaded that spring mat 102 by a pattern of mutually offset slats 104 is shaped. In each of the horizontal directions of the jump surface 106 thus borders on each of the slats 104 the spring mat 102 a gap. The slats are made of plastic and are rigid in themselves. The spring mat 102 itself is therefore essentially movable at the points where the slats 104 movably connected to each other.

At least part of the slats 104 of which the jumping mat 102 of the trampoline 100 are formed, like those in relation to 3 . 4 . 5 and 6 formed lamellae.

In particular, at least one of the lamellae 104 the spring mat 102 one in relation to 3 described lamellar body with a receiving space (not shown) in which a light element (not shown) is arranged. The recording room extends, as in 3 shown, starting from a formed in the tread surface of the lamellar body light exit opening (not shown) in the lamellar body into it. The light element comprises a generator for converting kinetic energy into electrical energy and a light source electrically connected to the generator. The light element is arranged in the receiving space such that the light source, when it is supplied by the generator with electrical energy, emits light in the direction of the tread side of the lamella through the light exit opening formed in the tread surface. Light emitted by the illuminant thus occurs while a user is on the trampoline 100 pops out through the light exit opening and can be perceived by the user, especially during jumping.

At the two ends of the ropes 108 are loops (not shown) arranged on which the ropes 108 and thus the jumping mat 102 on tension springs 110 For example, coil springs, are suspended. The tension springs 108 are on a frame 112 , in particular a steel frame, attached. The tension springs 108 hold the spring mat 102 in articulated storage and are with the steel frame 112 connected. The spring effect of the jump mat 102 thus results to a large extent from the elastic properties of the tension springs 108 , In an embodiment, not shown here, in which instead of wire ropes rubber parts are used, the rubber ropes are not usually attached to tension springs and the spring action depends essentially on the elastic properties of the rubber ropes used. The trampoline 100 is particularly suitable for being installed on a playground. The steel frame 112 with spring mat 102 is then preferably placed over a cavity in the soil at ground surface level.

In an embodiment not shown here, a fall protection border is furthermore provided, which is arranged above the frame and the tension springs. A fall protection frame is intended to prevent a direct impact of a user on the tension springs or on the steel frame. To a fall protection border is typically a shock-absorbing flooring, such as potted granules, provided to further reduce a risk of injury to a user.

2 shows a jumping mat 202 , which are connected by moveable slats 204 is formed. The slats 204 form a jumping surface 206 the spring mat 202 , The jumping mat shown 202 can be particularly advantageous as a component of a playground equipment for a playground, for example, as in 1 shown trampoline used.

The slats 204 the spring mat 202 each have an elongated lamellar body with two mounting holes (not shown) and are movable at the mounting holes with other fins 204 the spring mat 202 connected. The slats 204 have on a tread side a tread and the treads of the movably connected lamellae 204 form the jumping surface 206 ,

At least part of the slats 204 of which the jumping mat 202 are formed, like those in relation to 3 . 4 . 5 and 6 formed lamellae.

In particular, at least one of the lamellae 204 one in relation to 3 described lamellar body with a receiving space (not shown), which extends from a formed in the tread surface of the lamellar body light exit opening (not shown) in the lamellar body inside. In the receiving space, a light element (not shown) is arranged. The light element comprises a generator for converting kinetic energy into electrical energy and a light source electrically connected to the generator. The light element is arranged in the receiving space such that the light source, when it is supplied by the generator in the generator mode with electrical energy, emits light in the direction of the tread side of the lamella through the light exit opening formed in the tread surface. So if a user is on the jump mat 202 jumps and the spring mat 202 By supplying kinetic energy through a jump contact, a generator can pick up at least a portion of the kinetic energy supplied by a user and convert it into electrical energy. The electrical energy generated by the generator is then transmitted to the light source and converted by the light source into visible light. The generated light can then be emitted by the user while jumping on the jumping mat 202 be perceived.

3 shows a lamella 300 with a lamellar body 302 that has a recording room 308 in which a light element 318 is arranged. In the 3 Slat shown is particularly advantageous part of a like in 1 and 2 shown jumping mat.

The slat 300 comprises an elongate lamellar body 302 with a tread 304 on a side of the step 306 of the lamellar body 302 is formed. In the lamellar body 302 is a recording room 308 trained, one of the tread 304 trained light exit openings 310 in the lamellar body 302 extends into it. In the embodiment shown, the receiving space extends 308 but not by the lamellar body 302 , The kick side 306 opposite side 312 has accordingly no opening.

The lamellar body 302 has two mounting holes 314 on, which are designed as guided through the lamellar body bushings. Each one of the bushings 314 is located at one of the longitudinal ends 316 the elongated lamellar body 302 , The bushings 314 run parallel to each other in a horizontal longitudinal plane parallel to the tread surface 304 is aligned. At the lead-through openings 314 can the slat 300 by connecting a cable (not shown) to further fins to connect one as in 1 and 2 produce jumping mat shown. The lamellar body 302 the slat 300 is made of plastic and is rigid in itself.

In the recording room 308 is a lighting element 318 arranged, which is a generator 320 which is designed to convert kinetic energy into electrical energy. The light element 318 furthermore comprises a light source 322 which is electrically connected to the generator 320 is connected and powered by the generator in the generator mode. The through the generator 320 generated electrical energy is therefore to the light source 322 transferred and from the bulb 322 converted into visible light. The light is emitted toward the light exit opening 310, so that the light can be perceived by a user.

In an embodiment not shown here, the generator 320 a coil and a permanent magnet. The permanent magnet is movably disposed in the interior of the coil along the longitudinal axis of the coil and induces a voltage in the coil by moving along the longitudinal axis inside the coil by electromagnetic induction. The permanent magnet moves straight line along the longitudinal axis inside the coil.

In the embodiment not shown here, the generator with the coil and the permanent magnet arranged in the interior of the coil is in the receiving space 308 the lamellar body 302 arranged such that the longitudinal axis of the coil perpendicular to the tread surface 304 of the lamellar body 302 is and the permanent magnet is arranged perpendicular to the tread surface of the disk body along the longitudinal axis of the coil in the interior of the coil movable. If the slat 300 kinetic energy is supplied, the inertial permanent magnet moves perpendicular to the tread surface 304 along the longitudinal axis of the coil.

In an embodiment, not shown here, in the tread 304 trained light exit opening 310 closed by a diffuser. The diffuser scatters in the direction of the light exit opening 310 emitted light, which by the light source 322 emitted light through the surface illumination of the light exit opening 310 may be more noticeable to a user.

4 shows a lamella 400 with a lamellar body 402 the three recording rooms 408 has, in each of which a light element 418 is arranged. In the 4 Slat shown is particularly advantageous part of a like in 1 and 2 shown jumping mat.

The slat 400 comprises an elongate lamellar body 402 with a tread 404 the on a kick 406 of the lamellar body 402 is formed. In the lamellar body 402 are three along the longitudinal axis of the lamellar body 402 spaced apart receiving spaces 408 formed, each extending from a light exit opening 410 in the lamellar body 402 extend into it. The in the lamellar body 402 trained recording rooms 410 However, do not extend through the lamellar body 402 so that the lamellar body 402 on the tread side 406 opposite side 412 has no openings.

The lamellar body 402 has two mounting holes 414 on, as by the lamellar body 402 Guided bushings are formed. Each one of the bushings 414 is located at one of the longitudinal ends 416 the elongated lamellar body 402 , The bushings 414 run parallel to each other in a horizontal longitudinal plane parallel to the tread surface 404 is aligned.

In each of the three recording rooms 408 is each a light element 418 arranged, which is a generator 420 which is designed to convert kinetic energy into electrical energy. Each of the lighting elements 418 furthermore comprises a light source 422 which is electrically connected to the respective generator 420 is connected and powered by the generator in the generator mode. Due to the fact that several light elements 418 in the lamella 400 are provided, the light emitted in common for a user is relatively well perceived.

The tread 404 still has a structuring 424 realized in the form of a nubby GRIPTEQ ^® surface. By structuring 424 a user is given an improved grip.

5 shows a lamella 500 with an elongated lamellar body 502 , the three along the longitudinal axis of the lamellar body 502 spaced apart light exit openings 510 and three openings formed on the side opposite the tread side 511 having. In the 5 Slat shown is particularly advantageous part of a like in 1 and 2 shown jumping mat.

Between the respective openings 510 . 511 extends a recording room 508 through the lamellar body 502 , In each of the recording rooms 508 is a lighting element 522 arranged, which is a generator 520 which is designed to convert kinetic energy into electrical energy. Each of the lighting elements 518 furthermore comprises a light source 522 which is electrically connected to the respective generator 520 is connected and powered by the generator in the generator mode.

In the embodiment shown, the light exit openings 510 smaller than the one on the opposite side of the kick 512 of the lamellar body 502 trained openings 511 , Advantageously, they are in the respective receiving spaces 508 arranged light elements 522 thereby from the kicking side 506 out of reach for a user.

In the embodiment shown, the light exit openings 510 and those on the opposite side 512 of the lamellar body 502 trained openings 511 designed so that a corresponding light element 522 only by the on the side of the kick 506 opposite side 512 trained opening 511 of the lamellar body 502 from the lamellar body 502 can be removed. In particular, a corresponding light element 522 So only from the side of the kick 506 opposite side 512 in the recording room 508 be inserted or removed.

The lamellar body 502 has two mounting holes 514 on, as by the lamellar body 502 Guided bushings are formed. Each one of the bushings 514 is located at one of the longitudinal ends 516 the elongated lamellar body 502 , The bushings 514 run parallel to each other in a horizontal longitudinal plane parallel to the tread surface 504 is aligned.

In the embodiment shown is on the lamellar body 502 on the side of the kick 506 opposite side 512 a closure element 524 appropriate. The closure element 524 closes the opposite side of the tread side 512 of the lamellar body 502 trained openings 511 of the lamellar body 502 , Through the closure element 524 can those in the recording rooms 508 arranged light elements 522 be protected from being removed and from external environmental influences. In various embodiments not shown here is the closure element 524 by a screw or by an adhesive connection or by a cast connection fixed to the lamellar body 502 connected.

6 shows a plan view of a blade 600 with respect to the elongated lamellar body 602 laterally formed broadening 612 the tread 604 , In the 6 Slat shown is particularly advantageous part of a like in 1 and 2 shown jumping mat.

The slat 600 comprises an elongate lamellar body 602 with a tread 604 on one side of the lamellar body 602 is formed. The lamellar body 602 has three along the longitudinal axis of the lamellar body 602 spaced apart receiving spaces 608 on, each extending from a light exit opening 610 in the lamellar body 602 extend into it.

The tread 604 of the lamellar body 602 continues to broaden 612 on, centered between two each at one of the two longitudinal ends 616 the elongated lamellar body 602 formed mounting holes (not shown), wherein the mounting holes according to the in 3 . 4 . 5 shown mounting holes can be formed. The area of lateral broadening 612 the tread 604 is thus between the at the longitudinal ends 616 arranged fastening openings. In the places of the fastening openings, at which the lamella 600 can be connected to other slats, is the tread 604 so not widened.

The treads 604 still has a structuring 614 , which is in the form of a dimpled GRIPTEQ ^® surface.

7 shows a circuit for a light element 700 with a generator 702 and two bulbs 704 , which as light emitting diodes 706 are formed.

The generator 702 has a coil 708 and a permanent magnet 710 on. The permanent magnet 710 is in the interior of the coil 708 movable along the longitudinal axis of the coil 708 arranged and induced by moving along the longitudinal axis inside the coil 708 by means of electromagnetic induction, a voltage in the coil 708.

If the generator 702 So kinetic energy is supplied, the inert permanent magnet 710 inside the coil 708 set in motion and the kinetic energy of the permanent magnet 710 through the coil 708 converted into electrical energy. The electrical energy is in the form of a voltage to the two parallel LEDs 706 transmit, which convert the electrical energy into visible light. The generated light can be emitted through a light exit opening of a lamellar body, not shown here, and perceived by a user. In the embodiment shown, therefore, a light element 700 with two bulbs 704 shown, both from the same generator 702 be powered in generator mode with electricity. As a result, the light output per light element can be increased.

8th shows a lamella 800 with a lamellar body 802 that has a recording room 808 includes in that a light element 818 is arranged. The recording room 808 is in the elongated lamellar body 802 arranged. The lamellar body 802 also has two mounting holes 814 up and on a kick 806 a tread 804 ,

The light element 818 includes a generator 820 for converting kinetic energy into electrical energy. If the slat 800 Part of a jump mat is and this is deflected, the jump mat supplied kinetic energy can be partially absorbed by the generator and converted into electrical energy. The light element 818 also includes one with the generator 820 electrically connected light source 822 , If the generator 820 kinetic energy is supplied, the generator converts 820 this into electrical energy and gives the electrical energy to the bulb 822 from. The light source converts the electrical energy into light. The light element 822 is arranged so that a lighting of the bulb 822 from outside the lamella 800 and especially for a user who supplies kinetic energy to the generator is visible. Because the slat 800 has no opening through which the emitted light can be emitted, the lamellar body is preferably formed of a bright, translucent material, so that a lighting of the bulb is visible from outside the lamella. The material used is thus at least partially transparent to the emitted light.

The lamella shown here only schematically 800 , with an unopened recording room 808 in which a light element 818 is arranged, for example, can be produced by injection molding. The light element 818 is then overmolded with a material and then is usually completely enclosed by the material. Preferably, an injection mold is used for this purpose, which already dictates the outer shape of the finished lamella.

9 shows a lamella 900 with a lamellar body 902 the three interconnected recording rooms 904 . 906 . 908 includes. The recording rooms 904 . 906 . 908 are designed such that one or more light elements (not shown) can be arranged in them. The recording rooms 904 . 906 . 908 can then be closed or shed, for example, with a closure element (not shown) or shed first and then closed. The lamellar body 902 has mounting holes 914 on, which are provided so that a closure element by means of a screw or plug connection to the lamellar body 902 can be attached.

The lamellar body 902 has an elongated shape and has in the central region a with respect to the elongated lamellar body 902 trained lateral broadening 910 on. Lateral broadening 910 located between the two longitudinal ends 912 the longitudinally slat body 902 , The lamellar body 902 also includes two attachment openings (not visible in this view), each in one of the two sections between one of the longitudinal ends 912 and the area of lateral broadening 910 the longitudinally slat body 902 are arranged.

The slat shown here 900 does not have any in the tread 916 trained opening up. Depending on the design of the light element to be used can in the tread 916 For example, four arranged at regular intervals along the longitudinal direction of the elongated plate body light exit openings or a comparatively large, above the central receiving space 906 be arranged arranged light exit opening. The light exit openings can be made as required by drilling in the tread.

10a) shows a plan view of a light element 1000 , In 10b) is a side view of the same light element 1000 shown. The light element 1000 is intended for one of the three recording rooms of the 9 to be inserted lamella. In particular, in each of the two outer receiving spaces each have a light elements 1000 become.

The light element 1000 has a generator 1002 and two with the generator 1002 electrically connected bulbs 1004 on. The generator 1002 includes a coil 1006 that is around a coil carrier 1008 is wound. In the interior of the bobbin 1008 a permanent magnet (not shown) is movably arranged. That is, if the generator 1002 kinetic energy is supplied, the permanent magnet can move along the longitudinal axis through the interior of the bobbin and thus through the coil interior back and forth. By moving the permanent magnet inside the coil, the magnetic flux density changes locally for the coil, thereby inducing an electrical voltage in the coil according to the principle of electromagnetic induction. The sink 1006 is in a middle section of the bobbin 1008 arranged. In the sections of the bobbin 1008 in which there is no coil 1006 is located in the interior of the bobbin, for example, a damping material (not shown), preferably a foam may be arranged. At the two bases is the bobbin 1008 each with a lid 1010 locked.

The bulbs 1004 There are LED's on a carrier 1012 are attached. The carrier 1012 has an opening through which the coil carrier 1008 until the beginning of the coil 1006 is performed. The legs of the LED's are here by the wearer 1012 guided and so in electrically conductive contact with the coil that one in the coil 1006 induced voltage can be transmitted to the LED's. The carrier 1012 has a shape that fits precisely into a receiving space of the 9 shown blade can be used. Thus, in the in 9 shown lamella exactly next to each other three of the light elements shown here 1000 be used.

When the light element 1000 used in a receiving space is the coil 1006 of the generator 1004 with respect to a tread of a lamella arranged so that the longitudinal axis of the coil 1006 is perpendicular to the tread. The permanent magnet can then move freely in the coil interior perpendicular to the tread surface.

11a) shows a plan view of a light element 1100 and 11b) shows a side view of the same light element 1100 on a support 1102 is arranged. The light element 1100 can in the three interconnected recording rooms of in 9 slats are used.

The light element 1100 includes two generators 1104 . 1106 , each with two of the four bulbs 1108 . 1109 . 1110 . 1111 are electrically connected. The light element 1100 Thus, it can also be understood as two electrically independent light elements, which are on a common carrier 1102 are arranged.

As for 10a) and 10b) described, include the generators 1104 . 1106 one coil carrier each 1112 . 1113 with coil 1114 . 1115 in which a permanent magnet (not shown) is arranged. The coil carriers 1112 . 1113 are each until the beginning of the coils 1114 . 1115 through an opening in the carrier 1102 guided. The bulbs 1108 . 1109 . 1110 . 1111 , here's LED's, are on the carrier 1102 between the two generators 1104 . 1106 arranged. On the carrier 1102 are tracks 1116 . 1117 . 1118 . 1119 guided, which makes an electrically conductive contact between the LED's 1108, 1109, 1110, 1111 and the coils 1114 . 1115 produce.

If the bulb 1100 in the reception rooms of in 9 is inserted, the four LEDs 1108, 1109, 1110, 1111 are located in the central receiving space and each one of the generators 1104 . 1106 in one of the two adjacent reception rooms.

Claims (40)

A trampoline comprising a jumping mat formed by movably connected lamellae forming a jumping surface of the jumping mat, wherein the slats of the spring mat each have a slat body with at least two fastening openings and are movably connected to the fastening openings with further slats of the spring mat, - The lamellae have a tread on a tread and the treads of the movably connected lamellae form the jump surface, at least one of the lamellae has at least one receiving space in which at least one light element is arranged, - The at least one light element comprises at least one generator for converting kinetic energy into electrical energy and at least one electrically connected to the generator light source, of which the generator is arranged and designed such that it in the case of a deflection of the spring mat electrical energy to the light source emits, so that the bulb emits light, and - The lamp is arranged so that a lighting of the lamp is visible from outside the lamella. Trampoline after Claim 1 wherein the at least one generator comprises a coil and a permanent magnet, the coil of the generator being arranged with respect to the tread of the fin such that the longitudinal axis of the coil is perpendicular to the tread of the fin and wherein the permanent magnet is movable inside the coil is arranged along the longitudinal axis of the coil, so that when the jumping mat is deflected, the arranged inside the coil permanent magnet along the longitudinal axis of the coil and moves perpendicular to the tread of the blade. Sprung mat, preferably for a trampoline according to Claim 1 formed by movably connected lamellas which form a step surface of the jump mat, wherein - the lamellas of the spring mat each have a lamellar body with at least two attachment openings and are movably connected to the attachment openings with further lamellas of the jump mat, - the lamellas on a tread side have a tread surface and the treads of the mutually movably connected lamellae form the jump surface, at least one of the lamellae has at least one receiving space in which at least one light element is arranged, the at least one light element has at least one generator for converting kinetic energy into electrical energy and comprises at least one electrically connected to the generator light source, of which the generator is arranged and designed so that it emits electrical energy to the light source in the event of deflection of the spring mat, so that the light source Lic emitted, and - the light source is arranged so that a lighting of the illuminant is visible from outside the lamella. Jump mat after Claim 3 wherein the at least one generator comprises a coil and a permanent magnet, the coil of the generator being arranged with respect to the tread of the fin such that the longitudinal axis of the coil is perpendicular to the tread of the fin and wherein the permanent magnet is movable inside the coil is arranged along the longitudinal axis of the coil, so that when the jumping mat is deflected, the arranged inside the coil permanent magnet along the longitudinal axis of the coil and moves perpendicular to the tread of the blade. Slat (800), in particular as part of a jump mat according to Claim 3 , preferably for a trampoline according to Claim 1 wherein the lamella comprises - a lamellar body (802) with at least two attachment openings (814) and on a tread (806) has a tread surface (804), and - at least one receiving space (808) in which a at least one light element (818 ), and wherein - the at least one light element (818) comprises at least one generator (820) for converting kinetic energy into electrical energy and at least one light source (822) electrically connected to the generator (820), of which the generator ( 820) is arranged and configured to convert supplied kinetic energy into electrical energy and to emit the electrical energy to the illuminant (822) so that the illuminant (822) emits light, and - the illuminant (822) is arranged a lighting of the luminous means (822) is visible from outside the lamella (800). Lamella after Claim 5 , wherein the receiving space at least on one side to the outside open and arranged in the outer space light element is accessible through the opening from the outside. Lamella after Claim 6 wherein the opening is a light exit opening formed in the tread surface, and wherein the light element is disposed in the receiving space such that the light source, when supplied with electric power from the generator, directs light toward the tread side of the fin by the tread surface trained light exit opening emitted. Lamella after Claim 6 wherein the opening is a light exit opening formed in an outer surface opposite the tread surface, and wherein the light element is disposed in the receiving space such that the light source, when supplied with electric power from the generator, directs light toward the tread side opposite side of the lamella emitted by the formed in the outer surface light exit opening. Lamella after Claim 6 in addition to the opening having a light exit opening, wherein the opening on the side opposite the tread side of the lamella in the corresponding outer surface and the light exit opening is formed in the tread and wherein the at least one receiving space through the lamella body from the light exit opening to the on the the tread side opposite side formed opening of the fin body extends. Lamella after Claim 9 wherein the light exit opening is smaller than the opening formed on the opposite side of the lamella body on the tread side. Lamella after Claim 9 or 10 wherein the light exit opening and the opening formed on the opposite side of the lamellar body are designed such that the light element can be removed from the lamellar body only by the opening of the lamellar body formed on the side opposite the tread side. Lamella after at least one of Claims 5 to 11 wherein the lamellar body is formed by a bright, translucent material, so that a lighting of the illuminant is visible from outside the lamella. Lamella after at least one of Claims 5 to 12 wherein the at least one generator comprises a coil and a permanent magnet, wherein the permanent magnet is disposed in the interior of the coil movably along the longitudinal axis of the coil and induces a voltage in the coil by moving along the longitudinal axis inside the coil by electromagnetic induction. Lamella after Claim 13 in which the generator with the coil and the permanent magnet arranged inside the coil is arranged in the at least one receiving space the lamellar body such that the longitudinal axis of the coil is perpendicular to the tread surface of the lamellar body and the permanent magnet perpendicular to the tread surface of the lamellar body along the longitudinal axis of Coil is movably disposed inside the coil, so that the permanent magnet, by supplying kinetic energy, can move perpendicular to the tread surface along the longitudinal axis of the coil inside the coil. Lamella after Claim 13 or 14 wherein the permanent magnet comprises the alloy neodymium-iron-boron, cobalt-samarium, AINiCo, hard ferrites based on barium, strontium, PtCo, CuNiFe, CuNiCo, FeCoCr, martensitic steel or MnAIC. Lamella after at least one of Claims 5 to 15 wherein the at least one light element has a capacitor electrically connected to the at least one generator and the at least one light-emitting means for storing electrical energy generated by the generator and for delivering the stored energy to the at least one light-emitting means. Lamella after at least one of Claims 5 to 16 wherein the lamellar body has an elongated shape and the at least two attachment openings of the lamellar body by parallel to the tread surface and by the lamellar body Guided passage openings are formed, wherein the passage openings are respectively arranged at the two longitudinal ends of the longitudinally slat body and parallel to each other. Lamella after at least one of Claims 5 to 17 wherein the lamellar body of the lamella made of plastic or aluminum or wood or a combination of the aforementioned materials. Lamella after at least one of Claims 5 to 18 , wherein the lamellar body of the lamella is rigid in itself. Lamella after at least one of Claims 5 to 19 wherein at least one light element has exactly one generator and a plurality of light sources electrically connected to the generator, so that the plurality of light bulbs are supplied together with electrical energy generated by the exactly one generator during operation. Lamella after at least one of Claims 5 to 20 wherein the lamellar body has an elongated shape and the tread surface of the louver in a region of the tread surface has a lateral broadening formed with respect to the elongated lamellar body. Lamella after Claim 21 wherein the at least two attachment openings are respectively arranged at the two longitudinal ends of the elongated lamellar body and the region of the lateral widening of the tread surface is located between the attachment openings arranged at the longitudinal ends. Lamella after at least one of Claims 5 to 22 wherein the tread surface of the fin body has a structure for increasing the slip resistance. Lamella after at least one of Claims 6 to 23 wherein the opening is closed by a lens, and wherein the lens is adapted to scatter light emitted from the bulb in the direction of the opening. Lamella after Claim 24 wherein the lens has a material with fluorescent properties. Lamella after at least one of Claims 5 to 25 comprising a lamellar body of at least two receiving spaces, wherein the receiving spaces are separated by a wall of the lamellar body. Lamella after at least one of Claims 5 to 26 with a lamellar body, which identifies at least two interconnected receiving spaces. Lamella after at least one of Claims 5 to 27 wherein the lamella has a lamellar body with exactly three receiving spaces, in each of which a light element is arranged. Lamella after at least one of Claims 5 to 25 comprising a lamellar body having at least two interconnected receiving spaces, wherein in the interconnected receiving spaces a light element is arranged such that there is at least one generator of the light element in the one receiving space and at least one electrically connected to the generator light source in another receiving space. Lamella after Claim 29 which has an elongated fin body having exactly three interconnected receiving spaces arranged along the longitudinal direction of the fin body, wherein two light elements are arranged in the receiving spaces such that a light source of one of the light elements in the central receiving space and one electrically connected to a light source Generator of the corresponding light element is located in an adjacent to the central receiving space further receiving space. Lamella after at least one of Claims 5 to 30 wherein the lamella has at least one receiving space in which a plurality of light elements are arranged. Lamella after at least one of Claims 5 to 31 , wherein at least one light element comprises exactly one generator and exactly one light source. Lamella after at least one of Claims 5 to 32 wherein the light element comprises a housing, which is arranged in the at least one receiving space of the lamella, and in which the generator and the lighting means are arranged. Lamella after at least one of Claims 5 to 33 wherein at least one light element is potted in the receiving space. Lamella after at least one of Claims 5 to 34 wherein at least one light element is glued in the receiving space. Lamella after at least one of Claims 5 to 35 wherein the at least one light element comprises a damping element for acoustically damping the generator. Lamella after Claim 36 , wherein the damping element is formed by a foam. Lamella after Claim 36 or 37 wherein the damping element comprises two magnets, wherein the one magnet near the tread side in the receiving space and the other near the tread side opposite each other in the receiving space are arranged with different magnetic poles to each other and the generator is disposed between the two magnets. Lamella after at least one of Claims 6 to 38 wherein the lamellar body has a closure element which is attached to an outer surface of the lamellar body such that an opening to the receiving space of the lamellar body is closed by the closure element. Lamella after Claim 39 wherein the closure element is connected by a screw connection or by an adhesive connection or by a cast connection firmly with the lamellar body.

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