RU97608U1 - TRANSPARENCY STAND - Google Patents

Abstract

 A holder for transparent dishes, comprising a housing, a power source, a glow unit, an on / off unit, the housing configured to install the device on a flat surface and provided with a base and a lid configured to install transparent dishes on the lid, the base and the lid are connected to form in the body of the leaky cavity, the cover is made of a transparent material, with a second inner surface facing toward the cavity, and a second outer surface facing outward from the second A swarm of the inner surface of the cover is made, from the inside of the cover, reflective, from the side of the second inner surface in the cover there is a scattering lens, a power source, a glow unit and an on / off unit are located in the housing, a glow unit is connected to the power source through an on / off unit, a glow unit contains an LED of the red region of the spectrum, an LED of the green region of the spectrum and an LED of the blue region of the spectrum, the luminescence unit is configured to change the luminous intensity over time Each of the LEDs, the on / off unit is equipped with a flat spring, a fixed electrical contact and a button, while the button is located in the first hole made in the base and connecting the cavity with the environment, the button is equipped with a fourth protrusion placed to prevent the button from falling out of the first holes, a flat spring is fixed on the base and at one end is in contact with the button, a fixed electrical contact is fixed on the base, allowing electric

Description

Technical field

The utility model relates to decorative supports for glass vessels, which serve to illuminate these vessels and the liquids contained in them.

State of the art

A transparent vessel and a method for illuminating it are known (application for invention of the Russian Federation No. 2005100806). A transparent vessel contains a base and walls, while under the base there is a backlight unit optically coupled to the base and walls. The backlight unit has a housing that is sealed under the base. The backlight unit contains light elements, an autonomous power source and a device for controlling operating modes. The device turns on by push or shock. The vessel is made in the form of a glass, wine glass, decanter, glass or vase.

The disadvantages of the known technical solutions are limited application and design complexity.

The closest technical solution (prototype) is a stand for transparent dishes with backlight (RF patent No. 72832). A stand for backlit transparent dishes includes a glow unit, a glow mode control unit, an on / off unit, an autonomous power supply unit, and a sealed enclosure. The sealed case is made with the possibility of installing the device on a flat horizontal surface and installing transparent dishes on the top of the device, made in the form of a wine glass, glass, vase, decanter, bottle. The glow unit contains at least one light element emitting light of at least one color. The on / off unit is made and arranged to automatically turn on the device when installing dishes on the device and automatically turn off when removing dishes from the device. In this case, the luminescence unit is connected optically to transparent dishes.

The disadvantage of the prototype is the complexity of the design.

The purpose of the proposed utility model is to simplify the design.

This goal is achieved due to the fact that the stand for transparent dishes contains a housing, a power source, a glow unit, an on / off unit, and the housing is configured to install the device on a flat surface and is equipped with a base and a lid configured to be installed on the cover of transparent dishes , the base and the lid are connected with the formation of an unpressurized cavity in the housing, the lid is made of a transparent material, with a second inner surface facing the cavity and a second outer the surface facing outward, from the side of the second inner surface, the cover is made, from the inside of the cover, reflective, from the side of the second inner surface in the cover there is a scattering lens, a power supply, a glow unit and an on / off unit are placed in the housing, the glow unit is connected to the power source through the on / off unit, the luminescence unit contains a red spectrum LED, a green spectrum LED and a blue spectrum LED, the luminescence unit is made possible change in time of the intensity of the luminescence of each of the LEDs, the on / off unit is equipped with a flat spring, a fixed electrical contact and a button, while the button is placed in the first hole made in the base and connecting the cavity with the environment, the button is equipped with a fourth protrusion arranged preventing the button from falling out of the first hole, a flat spring is fixed to the base and contacts the button at one end, a fixed electrical contact is fixed to Again, with the possibility of electric contact with a flat spring when a button is pressed, the scattering lens is located above the luminescence unit, the luminescence unit is optically connected to transparent glassware through the scattering lens and the transparent cover material.

Brief Description of the Drawings

The utility model is illustrated in the drawing (Fig.1, 2), where Fig.1 shows a top view of the device without a cover, Fig.2 shows a side view in section.

Utility Model Disclosure

The drawing shows: power source 1, base 2, glow unit 3, first protrusion 4, second protrusion 5, flat spring 6, first hole 7, button 8, fixed electrical contact 9, shell 10, third protrusion 11, cover 12, opaque layer 13, second hole 14, scattering lens 15, second outer surface 16, second inner surface 17, first rounding 18, second rounding 19, first outer surface 20, second support 21, first inner surface 22, fourth protrusion 23, bend 24, first support 25.

The main elements of the device are a base 2, a cover 12, a shell 10, a power source 1, a glow unit 3, a stationary electrical contact 9, a flat spring 6 and a button 8.

In a particular case, the base 2 is made in the form of a round plate. The execution of the base 2 of any other form is possible. The base 2 has a first inner surface 22 and a first outer surface 20. The first inner surface 22 faces the lid 12, described later. The first outer surface 20 is facing outward. In the base 2, the first hole 7 is made. The first hole 7 is made through. The axis of the first hole 7 is perpendicular to the first inner surface 22 and the first outer surface 20. The first hole 7 is located near the center of the base 2. The first hole 7, in the particular case, is made round. The first hole 7 may be made in any other shape similar to the shape of the button 8, described later. The dimensions of the first hole 7 are larger than the dimensions of the button 8, described later. Along the perimeter of the base 2 from the side of the first inner surface 22, the first protrusion 4 and the second protrusion 5 are made. The first protrusion 4 and the second protrusion 5 are made annular. The diameter of the first protrusion 4 is made smaller than the diameter of the second protrusion 5. The first protrusion 4 and the second protrusion 5 are perpendicular to the base 2. The height of the first protrusion 4 from the base 2 to the edge of the first protrusion 4 is greater than the height of the second protrusion 5 from the base 2 to the edges of the second protrusion 5. The width of the second protrusion 5 is made equal to the thickness of the material from which the shell 10 is made, described below.

On the base 2, on the side of the first inner surface 22, the first support 25 and the second support 21 are located. The first support 25 and the second support 21 are made in the form of cylindrical protrusions. The first support 25 and the second support 21 are located on the same chord, not passing through the center of the base 2. In this case, the first hole 7 is located between the first support 25 and the second support 21. The base 2 can be made with a compartment for placement of a power source 1 described therein Further. The compartment, in a particular case, is a part of the base 2, bent towards the first inner surface 22. In the compartment for the power source 1 there are small slots designed to exit additional contacts from the power source 1, described later. When this compartment is equipped with a means of opening and closing the compartment located on the side of the first outer surface 20. In this case, the means of opening and closing the compartment is located in the same plane with the first outer surface 20.

In the particular case, the cover 12 is made in the form of a round plate. Possible implementation of the cover 12 of any other shape. The shape and size of the cover 12 is made similar to the shape and size of the base 2. The cover 12 is made of transparent material. Transparent materials are materials that transmit light, such as colored glass, frosted glass, transparent plastics and more (the definition of transparent is given, for example, on the website http://slovari.yandex.ru/dict/ushakov/article/ushakov/16-4/us393421 .htm? text =% D0% BF% D1% 80% D0% BE% D0% B7% D1% 80% D0% B0% D1% 87% D0% BD% D1% 8B% D0% B9 & stpar3 = 1.1). The lid 12 has a second inner surface 17 and a second outer surface 16. The second inner surface 17 of the lid 12 faces the base 2. The second outer surface 16 of the lid 12 faces outward. The edges of the lid 12 are bent around the perimeter to form a second rounding 19. The edges of the lid are bent towards the second inner surface 17 perpendicular to it. The diameter of the cover 12 along the edges from the side of the second inner surface 17 is made larger than the diameter of the first protrusion 4 of the base 2.

A scattering lens 15 is located in the central part of the cover 12. The scattering lens 15 is made as a spherical recess from the side of the second inner surface 17. From the side of the second outer surface 16, the third protrusion 11 is made on the cover 12. The third protrusion 11 is made in a particular round shape. The height of the third protrusion 11 is made equal to the thickness of the material from which the shell 10 is made, described below. In this case, the cover 12, the second rounding 19, the scattering lens 15 and the third protrusion 11 are aligned. An opaque layer 13 is formed on the second inner surface 17. The opaque layer is reflective, i.e. rays of light falling on an opaque layer are reflected from it. The opaque layer 13 in a particular case is made of paper. The opaque layer 13 in a particular case is attached to the second inner surface 17 with an adhesive. The opaque layer 13 can be made, for example, of film or paint. In the central part of the opaque layer 13, a second hole 14. A second hole 14 is made equal to the diameter of the scattering lens 15. The diameter of the opaque layer 13 is made equal to the diameter of the third protrusion 11 or greater than the diameter of the third protrusion 11.

The cover 12 is connected to the base 2 with the formation of strips between them. In this case, the first inner surface 22 faces the second inner surface 17. The curved edges of the cover 12 are located between the first protrusion 4 and the second protrusion 5 of the base 2. In this case, the cavity is leaky, i.e. communicating with the environment, for example, through the first hole 7 in the base 2.

The connection of the base 2 with the cover 12 in a particular case is made using screws. For this, on the basis of 2 from the side of the first inner surface 22 and on the cover 12 from the side of the second inner surface 17, corresponding connecting protrusions with threaded holes are made. The connecting protrusions are made in the form of cylinders attached to the base 2 or to the cover 12 with one of the ends. The threaded holes are made coaxially with the connecting protrusions. In the particular case, the connecting protrusions are made three on the base 2 and three on the cover 12. The threaded holes in the connecting protrusions on the base 2 are made through, and the threaded holes in the connecting protrusions on the cover 12 are made only from the side of the second inner surface 17. The connecting protrusions with threaded holes on the base 2 and the connecting protrusions with threaded holes on the cover 12 are made in pairs coaxially. It is possible to connect the base 2 with the cover 12 in other ways, for example, by making a threaded connection on the first protrusion 4 of the base 2 and on the edges of the cover 12.

The shell 10 in a particular case is made in the form of a flat ring. It is possible to perform shell 10 of any other shape. The shape and size of the shell 10 are made similar to the shape and size of the part of the cover 12 near the second rounding 19. The edges of the shell 10 with a large diameter are bent to form the first rounding 18. The smaller diameter of the shell 10 is made equal to the diameter of the third protrusion 11. The distance from the edge of the shell 10 s smaller diameter to the first rounding 18 is made equal to the distance from the third protrusion 11 to the second rounding 19. The height of the curved edges of the shell 10 is made equal to the height of the curved edges of the cover 12. The diameter of the curved edges of the shell 10 in more than the diameter of the bent edges of the cover 12. The shell 10 is located on the second outer surface 16. The edge of the shell 10 with a smaller diameter is adjacent to the edges of the third protrusion 11. The bent edge of the shell 10 is located on the second protrusion 5 of the base 2.

The power source 1 may be a battery, for example rechargeable. The power source 1 in a particular case is located in the compartment for the power source 1. In this case, additional contacts are threaded into the slot of the compartment, providing the connection of one of the outputs of the power source 1 with one of the edges of the stationary electrical contact 9, described later, of the other output with one of the outputs of the unit Glow 3, described later.

The glow unit 3 consists of three LEDs combined in one housing. One of the LEDs emits light in the range of red colors, the other LED emits light in the range of blue colors, the third LED emits light in the range of green colors. LEDs are placed in a housing made in the form of a hemisphere. Moreover, the dimensions of the housing are smaller than the sizes of the scattering lens 15. The luminescence unit 3 is configured to automatically switch colors. In this case, there is a change of colors with each other, as well as their mixing. The glow unit 3 is located between the Central part of the base 2 and the scattering lens 15. The glow unit 3 has two connecting contacts. One of the connecting contacts of the glow unit 3 is connected to one of the outputs of the power source 1, the other connecting contact of the glow unit 3 is connected to a flat spring 9, described below. Moreover, between the power source 1 and the glow unit 3 on the base 2 from the side of the first inner surface 22 can be made additional support. The additional support is designed to fix the conductor connecting the glow unit 3 to one of the outputs of the power source 1. In this case, the first support 25, the second support 21 and the additional support are located at the same distance from each other and from the center of the base 2.

Fixed electrical contact 9 in the particular case is made in the form of a rectangular plate. The fixed electrical contact 9 is made of an electrically conductive material, such as metal. One of the ends of the fixed electrical contact 9 is connected to the other output of the power source 1. The fixed electrical contact 9 with the middle part is fixed to the first support 25, for example, using a screw. For this, a threaded hole is made in the first support 25 and a hole for a screw is made in the stationary electrical contact 9. The other end of the fixed electrical contact 9 is located above the first hole 7 made in the base 2. In this case, the fixed electrical contact 9 can be bent to allow the other end to be placed at some distance from the first inner surface 22.

The flat spring 6 in a particular case is a rectangular plate with a bend 24 at one end. The flat spring 6 is attached with the end without bending 24 to the first protrusion 4 of the base 2. The flat spring 6 is fixed with the middle part on the second support 21, for example using a screw. For this, a threaded hole is made in the second support 21 and a hole for a screw is made in the flat spring 6. The end of the flat spring 6 with bend 24 is located above the first hole 7 made in the base 2. In this case, the bend 24 is turned to the side opposite to the base 2. The end of the flat spring 6 with bend 24 is located between the end of the stationary electric contact 9 located above the first hole 7, and a first hole 7 with a button 8 described later. The bend 24 is located at some distance from the end of the stationary electrical contact 9 located above the first hole 7. The end of the flat spring 6 with bend 24 presses the button 8 to the base 2. The flat spring 6 is fixed to allow the bend of the end with bend 24 from the base 2, with external impact on it, and back to base 2 under the action of elastic force. Flat spring 6 works on bending. The flat spring 6 is made of electrically conductive material, such as metal. In this case, the flat spring 6 also performs the function of a movable electrical contact. By a movable electrical contact is meant an eclectic contact that moves from a stationary electrical contact 9 and vice versa.

The on / off unit is a button 8. Button 8 in the particular case is made in the form of a straight cylinder having a circle in cross section. The length of the button 8 along the axis is greater than the thickness of the base 2. The diameter of the button 8 is made smaller than the diameter of the first hole 7. At one of the ends of the button 8, a fourth protrusion 23 is made. The fourth protrusion 23 is circular. The button 8 is located in the first hole 7, made in the base 2, with a gap providing free movement of the button 8 in the direction of the axis. In this case, the cavity formed between the cover 12 and the base 2, communicates with the environment through this gap. The fourth protrusion 23 is located on the side of the first inner surface 22. The butt of the button 8, opposite the end face with the fourth protrusion 23, protrudes above the first outer surface 20.

Utility Model Implementation

The utility model is implemented as follows.

The base 2 and the cover 12 are obtained, for example, by stamping. In this case, the cover 12 is made of a transparent material. The base 2 and the cover 12 are performed as previously described. The opaque layer 13, for example, is cut out of paper, and is attached to the second inner surface 17, for example using an adhesive. A fixed electrical contact 9, a flat spring 6, a glow unit 3, a button 8 and a power source 1 are located on the base 2 as previously described. Then connect the cover 12 with the base 2, as previously described, and put on the casing 10.

The user places the device with the first outer surface 20 on a flat surface, for example on a table. In this case, the base 2 is adjacent to a flat surface with one of the edges and button 8, i.e. the first outer surface 20 is at an angle to a flat surface. The user places on the second outer surface 16 a transparent dish (vessel), for example a bottle, glass or vase. A transparent vessel acts on the device. Under the action of a transparent vessel, the device is positioned in such a way that the first outer surface 20 over the entire area abuts against a flat surface on which the device is mounted. The butt of the button 8, previously protruding above the first outer surface 20, is buried in the device and is located in the same plane as the first outer surface 20. In this case, the fourth protrusion 23 of the button 8 lifts the end of the flat spring 6 with bend 24 from the first inner surface 22. Bend 24 flat springs 6 are electrically connected to the end of the fixed electrical contact 9. The connection of the flat spring 6 with the fixed electrical contact 9 closes the electrical circuit. As a result of the closure of the electrical circuit, the glow unit 3 emits light rays of red, green, blue, and also from various combinations. The color change of light rays occurs automatically with an interval and sequence programmed in the glow unit 3. Light rays fall on the scattering lens 15, in which they are refracted. After exiting the scattering lens 15, the rays scattered in it fall onto a transparent vessel, causing the decorative glow effect of a transparent vessel. The opaque layer 13, located on the second inner surface 17, reflects the rays that fell from the scattering lens into the transparent material of the lid on a transparent vessel. Thus, the glow unit is optically coupled to a transparent vessel. In this case, the opaque layer 13 closes the internal contents of the device from the user. After removing the transparent vessel from the device, the flat spring 6 under the action of the elastic force takes its initial position. The end of the flat spring 6 with the bend 24 presses the fourth protrusion 23 against the first inner surface 22. Button 8 returns to its original position, i.e. the end face of the button 8, opposite the fourth protrusion 23, protrudes above the first outer surface 20.

Thus, the implementation of the device as previously described provides a simplification of the design.

Claims (1)

A holder for transparent dishes, comprising a housing, a power source, a glow unit, an on / off unit, the housing configured to install the device on a flat surface and provided with a base and a lid configured to install transparent dishes on the lid, the base and the lid are connected to form in the body of the leaky cavity, the cover is made of a transparent material, with a second inner surface facing toward the cavity, and a second outer surface facing outward from the second A swarm of the inner surface of the cover is made, from the inside of the cover, reflective, from the side of the second inner surface in the cover there is a scattering lens, a power source, a glow unit and an on / off unit are located in the housing, a glow unit is connected to the power source through an on / off unit, a glow unit contains an LED of the red region of the spectrum, an LED of the green region of the spectrum and an LED of the blue region of the spectrum, the luminescence unit is configured to change the luminous intensity over time Each of the LEDs, the on / off unit is equipped with a flat spring, a fixed electrical contact and a button, while the button is located in the first hole made in the base and connecting the cavity with the environment, the button is equipped with a fourth protrusion placed to prevent the button from falling out of the first holes, a flat spring is fixed on the base and at one end is in contact with the button, a fixed electrical contact is fixed on the base, allowing electric eskogo its contact with the leaf spring when the button is pressed, a negative lens is located above the glow unit, the emission unit is optically coupled to a transparent tableware through a diverging lens and a transparent cover material.