RU2794976C1 - Luminous frisbee disk - Google Patents

Abstract

FIELD: sports equipment.

SUBSTANCE: invention relates to sports equipment. The frisbee disc contains a case in the form of a thin-sheeted transparent structure round in plan with a convex front surface, on the inner surface of the structure along its center there is a nest, inside which there is an on/off unit and electronic components of the unit for lighting the front side of the case, including radially located on the same angular displacement from the socket on the rear side of the housing and optical elements of the illumination unit of the front side of the housing reaching the edge of the housing. The optical elements of the illumination unit of the front side of the housing are made in the form of LED strips with the optical part of at least a part of the LEDs facing the surface of the rear side of the housing. The electronic components for lighting the front side of the case include an axial motion sensor with a gyroscope, a memory unit containing digital images of static images, and a microprocessor connected to the memory unit, connected to a microcontroller, to the outputs of which LED conductors on LED strips are connected, or a microprocessor, associated with microcontrollers, the output of each of which is connected to the conductors of the LEDs on one LED strip, or a microcontroller based on a microprocessor, to the outputs of which the conductors of the LEDs on the LED strips are connected. A microprocessor with a microcontroller, or a microcontroller based on a microprocessor, or a microprocessor associated with microcontrollers, is connected to an axial motion sensor with a gyroscope and is configured to retrieve image data from the memory unit and issue signals to turn on the LEDs on each LED strip to display the picture as a fragment of a picture in pixel form in each tape, where the glow of one LED is considered to be one pixel, and the function of transferring the glow of the LED line related to a fragment of the picture on each LED strip in the direction against the rotation of the disk body at the time of its flight at an angle equal to or less than the angle between adjacent radially located LED strips, when receiving data from the axial motion sensor with a gyroscope on the presence of an angular displacement of the disk in the direction of its rotation, equal to or less than the angle between adjacent and radially located LED strips.

EFFECT: sports equipment improvement.

8 cl, 4 dwg

Description

The present invention relates to sports equipment and relates, in particular, to the design of the so-called flying discs - Frisbee discs, made with the function of illuminating the surface of the body.

A flying disc is the general name of a sports projectile, which is a plastic disc with curved edges with a diameter of 20-25 cm. The disc is made in such a way that lift is created during its flight, which makes it possible to throw discs over considerable distances and with great accuracy. Most Russian-speaking people will call such a disk a "flying saucer". The next most popular option would be the Frisbee. People who are involved in various sports that use a flying disc simply call it a "disc" or "plate". "Frisbee" is technically not a common name for flying discs, but a trademark of Mattel's toy division of Wham-O Corporation. Similar to the situation with the name of any copiers copiers, the word "frisbee" is used to refer to flying discs in general.

To cope with the 4 physical forces (traction, gravity, lifting and air resistance), the disk must be kept by rotating around its own center. To fly, it needs to have convex and concave surfaces. Above the convex, the flow around the air will accelerate, under the concave it will slow down. Higher speed will create lower pressure and lift will be born. As a rule, the convex surface is thin in thickness, and the bent edge is thick. Since the main mass is concentrated at the edges, the flight and rotation will be more stable than with a flat product. A plate "with sides" resists air more, but the effects are distributed evenly. For example, thanks to the trailing edge, the rear lift is increased and the disc does not tip over.

Thus, a frisbee disc is known, containing a plastic case, which is a thin-sheet structure round in plan, the front part of which is made convex and is a fragment of a spherical surface, along the edges of which an edge is made, bent in the direction opposite to the convexity, and on the inner surface of the structure along its in the center there is a socket with a side wall, closed by a lid and inside of which there is one LED, a power source and an on / off button for the body lighting unit, which includes a set of optical fibers extending along the inner surface of the body from the side wall of the socket through openings in it and reaching to the edge of the rib housing, with each optical fiber facing from one end to the luminous part of the LED fixed in the center of the disk in the socket (US 2005090177, A63H 33/18, A63H 33/22, publ. 28.04.2005).

This decision is accepted as a prototype for the declared object.

In the known solution, optical fibers are used to propagate light from the LED over the entire surface of the housing. This makes it possible to see the illuminated disk during its flight and notice the approximate place of its fall and then find it on the ground. This static illumination of the disk is used for visible control of the flying disk and the place of its fall and does not carry any other functional load.

On the disk, illumination with optical fibers is stationary, and when the disk rotates in flight, the illumination image also rotates in synchronous mode with the rotation of the disk. You can play with a Frisbee disc both individually and in group sessions or in a team on the courts. During a team game or during competitive competitions, there can be quite a lot of discs in the air flying along different trajectories in one or in different directions. In this case, it becomes difficult to keep track of one's own disk among the simultaneously flying disks with supposed illumination of the hulls. Regardless of the degree and type of coloring (from lighting) of the case, during rotation, the color gamut becomes uniform and all disks appear to be the same color - illuminated in the same color palette. This is due to the inertia of human vision (the effect is called POV - persistence of vision). Human vision does not have time to track the speed of changing the picture, which leads to the merging of changing pictures into a total mass of color effects. If the player's serial number is displayed on the disk, for example, the number "5", then when the disk rotates in its flight, the clarity of the image is disturbed, which begins to look like a mixed palette of several colors.

The disadvantage of this solution lies in the lack of operational and long-term reliability of the disk, which consists in insufficient structural strength, leading to structural failure. This is because the Frisbee disc is used as a game projectile, which is thrown according to the rules of the game or as part of entertainment. During such games, the disc is subjected to shock loads (in the event of a fall or hit against a wall, if the game is played in an enclosed area). In this regard, the body of modern Frisbee discs is made of polypropylene, which has high elastic-deformation resistance to dynamic loads. But the implementation of the case from modern material does not provide high reliability in terms of structural strength as a whole. For example, in a known solution, optical fibers are tightly packed into open grooves in the ribs and are held in them due to material friction. Upon impact, an oscillatory process occurs that squeezes these fibers out of the grooves due to the fact that the material of the body and, accordingly, the ribs differ in structure and elastic properties from the material of the optical fiber sheath.

The impact is also transmitted to the electronic components responsible for the illumination of the disc case. The poor operational reliability of the disk is also determined by the fact that the socket for electronic components itself is made as a separate part and is fixed in the center of the disk. Thus, at the points of attachment, a material structure is formed, which differs from the material structure of the parts to be joined. The strength of any disk is determined by the fact that it is able to take the peak external load in a separate local place. At the moment of loading, an oscillatory process occurs in the structure of the material, propagating in the direction from the point of application of the peak local load. Due to intermolecular bonds, this process propagates along the structure and dampens the frequency and amplitude of vibrations as they move away from the point of application of the load. Due to this, internal damping of the impact energy occurs within the elastic bonds of the material molecules.

If an excellent structure with a different arrangement of molecules and bonds between them appears on the path of propagation of an oscillatory wave, then the wave hits this structure without damping the energy. Places of gluing or welding of the socket and ribs are such structures. That is, the impact energy is transferred to other parts. This leads to the destruction of the disk structure and the area where the electronic components are located.

The present invention is aimed at achieving a technical result, which consists in increasing the recognition ability of a flying Frisbee disc by forming on the surface of a flying and rotating disc a stationary and non-rotating light image along with the disc on the entire surface of the body.

The specified technical result is achieved by the fact that in a luminous Frisbee disc containing a body in the form of a round thin-sheet transparent structure with a convex front surface, a nest is made on the inner surface of the structure in its center, inside which there is an on/off unit and electronic components of the front lighting unit sides of the housing, including optical elements of the illumination unit of the front side of the housing, radially located at the same angular offset from the socket on the rear side of the housing and reaching the edge of the housing, the optical elements of the illumination unit of the front side of the housing are made in the form of LED strips with the optical part facing at least part of the LEDs to the surface of the rear side of the case, the electronic components for lighting the front side of the case include an axial motion sensor with a gyroscope, a memory unit containing digital images of static images, and a microprocessor connected to the memory unit, connected to the microcontroller, to the outputs of which are connected conductors of LEDs on LED strips, or a microprocessor connected to microcontrollers, to the output of each of which are connected conductors of LEDs on one LED strip, or a microcontroller based on a microprocessor, to the outputs of which LED conductors of LEDs on LED strips are connected, a microprocessor with a microcontroller or a microcontroller based on a microprocessor or a microprocessor connected to microcontrollers, connected to an axial motion sensor with a gyroscope and configured to retrieve data about the picture from the memory unit and issue signals to turn on the LEDs on each LED strip to represent the picture as a fragment of a picture in pixel form in each strip, where the glow of one LED is considered to be one pixel, and the function of transferring the glow of the line of LEDs related to a fragment of the picture on each LED strip in the direction against the rotation of the disk body at the time of its flight at an angle equal to or less than the angle between adjacent radially located LED strips is also implemented, upon receipt from the axial motion sensor with a gyroscope of data on the presence of an angular displacement of the disk in the direction of its rotation, equal to or less than the angle between adjacent and radially located LED strips.

In this case, a microprocessor with a microcontroller or a microcontroller based on a microprocessor or a microprocessor associated with microcontrollers are connected by each output to each individual LED on the LED strips.

The drive can be equipped with a Bluetooth unit or a WiFi unit for remote control and data transfer to the microprocessor or microcontroller or download of the memory unit. And on the front side of the case, the disk in the center or on the back side of the case in the center, there is a USB socket. And the button of the unit for turning on / off the lighting of the case is displayed on the back side of the case.

In the disk, all optical parts of all LEDs can face the surface of the rear side of the housing or in the opposite direction from this surface, or the optical parts of some LEDs face the surface of the rear side of the housing, while the optical parts of other LEDs face in the opposite direction from this surface.

These features are essential and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

This utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

In FIG. 1 - general view of the Frisbee disk with a demonstration of the location of the LED strips;

in fig. 2 - shows the placement of the board in the socket and the LED strip in relation to the socket;

in fig. 3 - view of the board from one side;

in fig. 4 - view of the board from its other side.

According to the present invention, a new design of the Frisbee disc is considered, used as a luminous sports equipment capable of flying long distances without turning over. A feature of the claimed disk is its increased design feature, which determines its ability to implement the function of demonstrating luminous patterns on the body surface while maintaining the compositional integrity of these patterns when the disc rotates during flight. Also, a feature of the long-term operation of the electronic part of the disk is that the socket for these components is made integral with the case itself by 3D printing in order to exclude areas of stress concentration.

In general, the Frisbee disc contains a body made of a polymeric material, which is a thin-sheet structure round in plan, the front surface of which is made convex and is a fragment of a spherical surface, and along the edges of which an edge is made, bent in the direction opposite to the convexity of the front part. Thus, the body of the disc is made with an aerodynamic surface that provides the disc with flight stability in the air for a certain distance and the ability to rotate around its axis during the flight.

On the inner surface of the structure, in its center, there is a nest with a side wall with holes, closed by a lid and inside which are located the electronic components of the unit for lighting the case and controlling the glow of the LEDs.

On the rear surface of the structure, there are slots radially extending from the side wall for placing optical elements for forming an image on the surface of the transparent body. The optical elements of the illumination unit of the front side of the housing are made in the form of LED strips with the optical part of at least a part of the LEDs facing the surface of the rear side of the housing.

As an embodiment, all optical parts of all LEDs can face the surface of the rear side of the housing or in the opposite direction from this surface. Or, alternatively, the optical parts of some LEDs face the surface of the rear side of the housing, and the optical parts of other LEDs face in the opposite direction from this surface. Depending on the direction of the optical parts of the LEDs, it is possible to obtain illumination of only the outer front surface of the housing or illumination from the back side with a projection onto the front through the transparent walls of the housing or a housing with two-sided illumination in the form of a static picture.

A special feature is that the housing, the optical element sockets and the socket with a side wall for electronic components are made in one piece by 3D printing. The case can be made of polypropylene, which is very resistant to various mechanical stresses, is not afraid of water and high temperatures. At the same time, this material has an elastically deformed structure and the ability to restore its shape.

The electronic components for lighting the front side of the case include an axial motion sensor with a gyroscope, a memory unit containing digital images of static images, and a microprocessor connected to the memory unit, connected to a microcontroller, to the outputs of which LED conductors on LED strips are connected, or a microprocessor, associated with microcontrollers, to the output of each of which LED conductors on one LED strip are connected, or a microcontroller based on a microprocessor, to the outputs of which LED conductors on LED strips are connected,

A microprocessor with a microcontroller or a microcontroller based on a microprocessor or a microprocessor associated with microcontrollers is connected to an axial motion sensor with a gyroscope and is configured to retrieve image data from the memory unit and issue signals to turn on the LEDs on each LED strip to present the picture as a fragment images in pixel form in each strip, where the glow of one LED is considered one pixel, and are also performed by the function of transferring the glow of the line of LEDs related to the fragment of the picture on each LED strip in the direction against the rotation of the disk body at the time of its flight at an angle equal to or less than the angle between adjacent radially arranged LED strips, upon receipt from the axial motion sensor with a gyroscope of data on the presence of an angular displacement of the disk in the direction of its rotation, equal to or less than the angle between adjacent and radially located LED strips.

Below is an example of a specific implementation of the disc Frisbee (Fig. 1-4).

The basic element of the Frisbee disc, which determines its performance, is a resiliently deformable polymer body 1 with an outer aerodynamic surface (Fig. 1), which makes it possible for the disc to fly with simultaneous rotation (or without rotation) at a given distance. Therefore, the body 1 made of polymeric material is a thin-sheet structure round in plan, the front surface (front side) of which is convex and is a fragment of a spherical surface. Along the edges of the structure, an edge is made, bent in the direction opposite to the convexity of the front part (to form a lifting force). On the inner surface of the structure (on the back side) in its center there is a nest 2 with a side wall 3 with holes in it. The nest is closed with a separate cover 4.

On the rear surface of the housing structure, slots 2 radially extending from the side wall 3 and reaching the edge 3 of the housing are provided with seats for accommodating optical elements of the housing illumination unit. These places 4 are made hollow with the location of their cavities opposite the holes in the side wall 3 of the socket. The body 1, seats 4 and socket 2 with a side wall are made in the form of a single part by 3D printing. When using this method of manufacturing a body, a homogeneous structure is formed in the material of all its constituent elements without stress concentrators, both in the body of the body and at the points of transition from one surface to another. That is, the working conditions of the body are created exclusively in the elastic deformation mode.

When hitting an obstacle (for example, a tree or a wall), a collapse is formed on the body at the place of impact contact, resulting in the formation of an oscillatory wave inside the structure of the body material. With a homogeneous structure of the material, the wave passes in the direction of impact and exerts pressure on the molecules, which increase their own frequency and vibration amplitude in the range of elastic bonds with other molecules. This increase leads to the loss of impact energy and the dissipation of this energy, which is expressed in the loss of frequency and amplitude of the oscillatory process from the impact. Having reached the opposite edge, the wave returns with less energy and completely loses it at the point of impact. This process takes place in the range of the elastic characteristics of the body material. Such deformations for a homogeneous structure of a polymeric material are natural and are expressed in thousand cycles until the material ages and loses its elastic properties. Upon impact, the body experiences shape deformation, which is reflected in the shape of seats 4 in the zone of the impact direction line. But this form is being restored. This feature of the body with a homogeneous material structure allows the use of more complex electronic systems for illuminating the disc body, since the shock load is not transferred to them. Upon impact, the oscillation wave moves along the impact line and is reflected from the side wall 3 of the socket 2, returning in the opposite direction. In this regard, it became possible to place in the socket not only a power source (accumulator or battery) and an on / off button for the housing lighting unit, but also electronic components for controlling the glow of optical elements.

Each optical element of the housing lighting unit is made in the form of an LED strip 5, passed through the corresponding hole in the side wall 3 of the socket 2 and connected to the board 6 placed in the socket with electronic components for controlling the glow of the LEDs (Fig. 3 and 4).

A feature of the use of LED years is that all deformations that come to this element are perceived by the tape itself, that is, the base on which the LEDs are fixed. The LEDs themselves, which are sensitive to mechanical loads, are not subjected to these loads, but undergo a shift in their position at the installation site. That is, when the body hits an obstacle, the shape of the body is deformed, and inside the body the tape itself is deformed, as a carrier of LEDs, without transferring the deformation load to the optical elements. This important property and the fact that the deformation load from the impact does not go beyond the side wall of the socket made it possible to mount board 6 with electronic components for controlling the glow of the LEDs in the socket.

During installation, the operator passes the LED strip through the hole in the side wall of the socket until it stops at the end and attaches its conductive leads to the board. The tapes are located in the cavity of the ribs freely located at their locations. In this particular embodiment, each place for the LED strip is made in the form of a hollow radial rib, in the cavity of which the strip is located.

The electronic components for controlling the glow (Fig. 3 and 4) of the LEDs include a microprocessor element 7, 2-6 or 9-axis motion sensor 8 and a Bluetooth unit 9 or a WiFi unit (for remote control - for remote control and data transmission to the microprocessor or microcontroller or memory block loading). With such a composition, it becomes possible not only to highlight the disk for the visibility of its movement trajectory, but also to form dynamic or static pictures on the surface of the case (via Flash memory 10, which stores pictures displayed when the disk rotates). In order to keep the dimensions small, the components are mounted on both sides of the board 6 (FIGS. 3 and 4). So in FIG. 2 shows that the power supply 11 is located at the bottom of the socket. On one side of the board (Fig. 3), a microprocessor element, a motion sensor and a Bluetooth unit are fixed. And on the reverse side of the board (Fig. 4) there is a power on / off node 12 with a button, a USB connector 13 and a Flash memory 10, which stores pictures displayed when the disk rotates. In this example of execution, the button of the unit for turning on / off the lighting of the case is displayed on the back side of the case.

At the same time, in the slot, the board 6 is located at a point where there is no path for the process of vibration of molecules caused by impact. This became possible due to the implementation of the side wall of the socket at the same time with the body.

To ensure the connection of the disk to the computer on the front side of the case in the center there is a socket 14 of the USB connector (Fig. 1). Nothing limits the possibility of placing this connector on the back of the case.

And for ease of use, the on / off button of the body lighting unit is displayed on the back of the case.

The expression “microprocessor element 7” refers to one of the modern solutions: either a microprocessor connected to a microcontroller, to the outputs of which LED conductors on LED strips are connected, or a microprocessor connected to microcontrollers, to the output of each of which LED conductors are connected on one LED strip, or a microprocessor-based microcontroller, to the outputs of which LED conductors on LED strips are connected. Regardless of the execution (microprocessor with a microcontroller or microcontroller based on a microprocessor or a microprocessor associated with microcontrollers), the microprocessor element 7 is connected by each output to each individual LED on the LED strips, which allows it to programmatically output a signal to each LED separately. This is what allows you to form not a color mixture, but an image of a semantic or thematic plan.

As part of the electronic components for lighting the front or rear side of the housing, the memory unit, the function of which is performed by the Flash memory 10 associated with the microprocessor element 7, contains images of static images in digital form. The microprocessor element 7 is configured to retrieve image data from the memory unit and issue signals to turn on the LEDs on each LED strip to present the picture as a fragment of a picture in pixel form in each strip, where the glow of one LED is considered one pixel. At the same time, the microprocessor element 7 is connected to the axial motion sensor 8 with a gyroscope and is also designed to transfer the glow of the LED line related to the image fragment on each LED strip in the direction against the rotation of the disk body at the time of its flight at an angle equal to or less than the angle between adjacent radially arranged LED strips, when receiving data from an axial motion sensor with a gyroscope on the presence of an angular displacement of the disk in the direction of its rotation, equal to or less than the angle between adjacent and radially located LED strips.

Essentially, the pixel elements of the stationary picture formed by the LEDs on each LED strip are transferred when the Frisbee disc is rotated onto the LEDs of the adjacent LED strip that is located first in the counter-rotation direction of the disc body. In reality, at an angle equal to, for example, 1-5°, the discreteness of the transfer is not visible to the human eye due to the inertia of the vision itself. The angle, in fact, is the angular resolution of the picture, it is set in the firmware and depends on the step of the LEDs on the tapes and the number of LEDs on the tapes. By transferring a line of pixel elements on each LED strip, we mean turning off the glow of the LEDs and then turning them off in the pixel layout algorithm in which the LEDs on the adjacent LED strip were lit. The control signal for switching the LED lighting algorithms on the tapes comes from a 2-6 or 9-axis motion sensor 8.

How it's implemented:

- flexible tapes of addressable LEDs are located along the radii of the disk, each of which is controlled independently. There can be three or more such tapes;

- a motion sensor with a gyroscope is built into the disk, which measures the angular velocity and angular position of the disk;

- the control circuit receives information about the pictures to be displayed from the FLASH memory into which the pictures are preloaded. In general, pictures can be transmitted in real time via WiFi, Bluetooth or other radio channel;

- the algorithm of the control circuit reads data about the current picture and forms a set of pixels from it, which must be displayed on the LEDs at their spatial position at a given time:

- along with this, as the disk rotates, the algorithm reads data from the gyroscope and, when the required angular displacement is reached, displays the next formed column of pixels on the LEDs of each strip;

The previous two points are repeated through given equal angular displacements. For example, after each degree of rotation of the disk, a new set of pixels is formed and displayed on the LEDs, corresponding to the colors of the picture for a given spatial arrangement of the LEDs.

When a complete revolution of the disk is made, the controller starts drawing the picture again.

If, however, not a permanent picture is displayed, but a video sequence, then with each next turn, the next image of the video sequence is displayed. Thus, a sequence of pictures is formed, which looks like a stationary image on a rotating disk.

The present invention is industrially applicable and implemented in the framework of small-scale production. Experiments on shock loads show the stability and continuity of the electronic part of the disk, the preservation of the image on the surface without distortion and breaks. EFFECT: invention makes it possible to form on a rotating disk a picture that does not change due to rotation of the disk, which provides visual control over the movement of the disk in the air and the place of its fall.

Claims (8)

1. Luminous frisbee disc, containing a body in the form of a thin-sheeted transparent structure round in plan with a convex front surface in the form of a fragment of a spherical surface, on the inner surface of the structure in its center there is a socket, inside which there is an on/off unit and electronic components of the front side lighting unit housings, including optical elements of the housing front side lighting unit, radially located at the same angular offset from the socket on the back side of the housing and reaching the housing edge, characterized in that the optical elements of the housing front side lighting unit are made in the form of LED strips with the optical part reversed at least part of the LEDs to the surface of the rear side of the case, the electronic components of the lighting of the front side of the case include an axial motion sensor with a gyroscope, a memory unit containing digitally images of static images, and a microprocessor connected to the memory unit, connected to the microcontroller, to the outputs of which are connected to LED conductors on LED strips, or a microprocessor connected to microcontrollers, to the output of each of which LED conductors are connected on one LED strip, or a microcontroller based on a microprocessor, to the outputs of which LED conductors on LED strips are connected, a microprocessor with a microcontroller, or a microcontroller based on a microprocessor, or a microprocessor associated with microcontrollers, is connected to an axial motion sensor with a gyroscope and is configured to retrieve data about the picture from the memory unit and issue signals to turn on the LEDs on each LED strip to represent the picture in the form of a fragment of a picture in a pixel form in each strip, where the glow of one LED is considered one pixel, and are made with the function of transferring the glow of the line of LEDs related to the fragment of the picture on each LED strip in the direction against the rotation of the disk body at the time of its flight at an angle equal to or less than the angle between adjacent radially arranged LED strips, when receiving data from an axial motion sensor with a gyroscope on the presence of an angular displacement of the disk in the direction of its rotation, equal to or less than the angle between adjacent and radially located LED strips. 2. The disk according to claim 1, characterized in that a microprocessor with a microcontroller, or a microcontroller based on a microprocessor, or a microprocessor associated with microcontrollers, is connected by each output to each individual LED on the LED strips. 3. The disk according to claim 1, characterized in that it is equipped with a Bluetooth unit or a WiFi unit for remote control and data transfer to a microprocessor or microcontroller, or loading a memory unit. 4. A drive according to claim 1, characterized in that a USB socket is made in the center on the front side of the case. 5. A drive according to claim 1, characterized in that a USB connector is made on the back of the case in the center. 6. The disk according to claim 1, characterized in that the button of the unit for turning on / off the lighting of the case is displayed on the back side of the case. 7. Disc according to claim 1, characterized in that all optical parts of all LEDs face the surface of the rear side of the case or in the opposite direction from this surface. 8. The disk according to claim 1, characterized in that the optical parts of some LEDs face the surface of the rear side of the housing, and the optical parts of other LEDs face in the opposite direction from this surface.

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