EA003595B1 - Telescopic bottle - Google Patents

Abstract

1. A bottle containing transparent liquid and some amount of gas, for example, carbonated beverage, consisting of body and cover, a bottom part being made from transparent material and exceeding a diameter of bottom part of cover, which made also from transparent material, characterized in that the bottom of body and the bottom of cover are used as objective and ocular and preferably in vertical position of the bottle with liquid inside forms together a telescopic system, so a bottom of body and cover are at least partially limited and at least from one side (outside for example) are limited with axially symmetric optical refractor (spherical, for example), symmetric axes said refractors being coincided, forming optical axe of telescopic system, and a distance by optical axe between tops of nearest refractors of bottom of body -objective and front focal distance of bottom of cover-ocular. 2. A bottle according to claim 1, characterized in that the bottom parts of body and cover are made from materials, with refraction index equal to refraction index of liquid in the bottle, axially symmetric refractors limiting the bottom part of body and cover only from outsides. 3. A bottle according to claim 1, characterized in that only one component, as objective or ocular of telescopic system is made from material with refraction index equal to refraction index of liquid in the bottle, limited by axially symmetric refractors, and from other side as a lens and is limited by axially symmetric refractors from both (inside and outside) sides. 4. A bottle according to claim 1, characterized in that the bottom of the body is made as a lens and is limited by axially symmetric refractors from both (inside and outside) sides. 5. A bottle according to claim 4, characterized in that the body of the bottle is made form elastic material (polymeric, for example) and at least one part, containing a lens or attached with bottle detail, containing a bottle (orifice with cover for example) can possibly be after draining the bottle pressed inside of body of bottom part of body-objective with front focus of bottom part of cover ocular and creating a telescopic system without liquid between objective and ocular. 6. A bottle according to claim 1-5, characterized in that the cover is connected with the body by screw joint, the axe of which is coincided with optical axe of telescopic system, allowing to produce focusing of telescopic system by screwing and unscrewing the cover.

Description

The invention relates to the food industry and is intended for the storage of transparent drinking liquids, mainly carbonated beverages.

The level of technology

Analogs or prototypes of the invention, the applicant is not known.

Known glass bottles intended for the storage of food liquids (GOST 10117-91).

The disadvantage of these bottles is that they can be used only for its intended purpose - for storing liquids.

Telescopic systems are known from optics that make it possible to observe distant objects. Telescopic systems consist of two centered components of the lens and the eyepiece, which can be represented by two lenses or two optical refractive surfaces. In the first case, such a telescopic system is called a telescope, in the second - a telescopic lens. The condition of the telescopic system is such an arrangement of its constituent components so that the rear focus of the lens (lens or refracting surface facing the object being observed) coincides with the front focus of the eyepiece (lens or refracting surface facing the eye of the observer), for this the distance between them is optical the axis (the distance between the adjacent refractive surfaces of the lens and the eyepiece) must be equal to the sum of the back and front focal lengths of the lens and the eyepiece, respectively. (Zakaznov NP and others. Theory of optical systems, M., Mashinostroenie, 1992, p. 205).

The task of the invention

The problem to which the invention is directed, is to improve the consumer qualities of the bottle and give it new functionality.

Technical result

The technical result of the invention is to give the bottle the properties of the optical telescopic system and the possibility of its use as an observant device.

The invention

The mentioned task is achieved by the fact that the bottom parts of the body and the bottle cap act as an objective and eyepiece of the telescopic system and are made of transparent material limited from the outer and from the inner (or only from the outer) side with axisymmetric optical refractive surfaces (for example, spherical surfaces of the second and higher orders of magnitude, as well as flat), so that the symmetry axes of the refracting surfaces lie on one imaginary straight line, the so-called optical axis, and in order to The focus of the lens coincided with the front focus of the eyepiece, the distance along the optical axis between the vertices of the nearest refracting surfaces of the bottom of the lens housing and the bottom of the cover of the cue (the refracting surfaces of the one and the other bottom located at the smallest distance from each other) the sum of them, respectively, the rear and front focal segments. Since behind the lens and the front of the eyepiece (i.e. between them) there is a liquid having a greater optical density than the gas (air) located outside the system, the rear focal length of the lens and the front focal length of the eyepiece in the liquid will be greater than if there was gas between them. Therefore, the above-mentioned distance between the bottom of the body-lens and the bottom of the lid-eyepiece, which determines the axial size of the bottle, is made up of the corresponding focal lengths for the liquid medium, the value of which depends on the ratio of the refractive index of the liquid contained in the bottle and the refractive indices of the materials of the bottom of the body and the bottom bottle caps. When refracting the outer and inner surfaces of the bottom parts of the body and the bottle cap, i.e. when they are made in the form of lenses, they, together with the liquid contained in the bottle, form a complex optical system - a telescope. When optical only outer surfaces of the bottom parts of the body and bottle cap are used, the refractive index of the material from which they are made must be equal to the refractive index of the liquid contained in the bottle (their optical density must be the same) and then the internal surfaces in contact with the liquid may have arbitrary shape. In this case, the bottom parts of the body and the bottle cap (or rather their outer surfaces), together with the liquid contained in it, form the simplest optical system - a telescopic lens. Considering that in addition to liquid a bottle usually contains some insignificant amount of free (undissolved) gas, the effect of the present invention is possible only with this arrangement of gas accumulation in the bottle so that it does not violate the optical continuity of the liquid in the area close to the optical axis and does not distort the course of the image of the optical rays as a result of their additional refraction at the interface of liquid and gas having a random form. The simplest way to achieve this is to position the bottle in a position close to horizontal when gas accumulates in the uppermost part of the bottle volume at its wall and does not affect the course of the rays.

The technical result of the invention can only be achieved by forming the bottom parts of the body and the bottle cap in the form of an objective lens and an eyepiece and forming together with the liquid contained in the bottle of the telescopic system.

The technical result of the invention can be achieved with different versions of the bottom parts of the body and the bottle cap (lens and eyepiece): in the form of collecting lenses - according to the Kepler telescope design; in the form of collecting (lens) and scattering (eyepiece) lenses - according to the scheme of Galileo's telescope; in the form of convex surfaces of a biconvex telescopic lens; in the form of convex and concave surfaces of a convex-bent telescopic lens. The combined design of the lens and eyepiece, when the lens is a refractive surface, and the eyepiece is a lens (or vice versa), can also give the technical result of the invention.

The technical result can be achieved even if a certain part of the bottom surface of the body that performs the role of a lens does not have a spherical shape. For example, if any stiffening ribs are placed on the outer surface of the bottom of the case (to give the bottom greater strength) or protrusions (to give the bottle vertical stability when installed on a horizontal surface). A noticeable deterioration of image quality will not occur if the part of the bottom occupied by non-optical elements is negligible.

The technical result of the invention can be saved after emptying the bottle, made according to the scheme of the telescope. The combination of the rear focus of the bottom of the lens housing and the front focus of the bottom of the eyepiece cap, disturbed after the bottle is emptied due to the corresponding focal lengths of the lens and eyepiece reduced in the gas medium, is pressed by pressing or indenting one part of the bottle body containing the lens (for example, cover), to another part of the body in the direction (along) the optical axis. The body of the bottle in this case is made of elastic material (for example, polymer). Exact alignment of foci (focusing) in this and other cases can be done by unscrewing and screwing the lid, which is connected to the case by a threaded connection, the axis of which coincides with the optical axis of the telescopic system.

Explanatory drawings

FIG. 1 shows a telescopic bottle located horizontally, consisting of the body 1 and the screw connection of the lid 2 connected to it, containing liquid 3 and a certain amount of gas 4.

The bottom 5 of the housing 1 and the bottom 6 of the lid 2 of the bottle are made of a transparent material having a refractive index equal to that of the liquid 3 contained in the bottle. The outer surfaces of the bottom 5 and the bottom 6 are bounded by optical spherical surfaces, the axes of symmetry of which coincide and form the optical axis 7. The inner surfaces of the bottom 5 and bottom 6, in contact with the liquid 3, have an arbitrary shape. The outer surface of the bottom 5, which serves as the objective of the telescopic system, and the outer surface of the bottom 6, which performs the role of the eyepiece, are made outwardly convex, and the distance along the axis 7 between the tops of the outer surfaces of the bottom 5 and the bottom 6 is equal to the sum of the rear focal segment of the first and front focal segment of the second .

This telescopic bottle operates as follows. When the bottle is horizontal, gas 4 accumulates in the uppermost part of the bottle volume and does not affect the course of the optical rays 8 and 9 forming the image, parallel to the optical axis 7 at the entrance to the system. After refraction of the rays 8 and 9 on the outer surface of the bottom 5 of the housing 1, they intersect with the optical axis 7 at point 10, which is both the rear focus of the outer surface of the bottom 5 and the front focus of the outer surface of the bottom 6 and is located from these surfaces at a distance equal to their corresponding focal segments. After passing point 10 and refracted on the outer surface of the bottom 6, the rays 8 and 9 again become parallel to the optical axis 7 and form an inverted magnified image.

FIG. 2 shows a telescopic bottle located horizontally, consisting of a housing 1 and a screw connection of a lid 2 connected to it, containing liquid 3 and some gas 4. The bottom 5 of the housing 1 and the bottom 6 of the lid 2 of the bottle are made of a transparent material having a refractive index equal to the refractive index of the liquid 3 contained in the bottle. The outer surfaces of the bottom 5 and the bottom 6 are bounded by optical spherical surfaces, the axes of symmetry of which coincide and form the optical axis 7. The inner surfaces of the bottom 5 and bottom 6, in contact with the liquid 3, have an arbitrary shape. The outer surface of the bottom 5, which serves as the objective of the telescopic system, is convex outward, the outer surface of the bottom 6, which serves as an eyepiece, is concave inward and the distance along axis 7 between the tops of the outer surfaces of the bottom 5 and the bottom 6 is equal to the sum of the back focal length of the first and front focal segment of the second, but since the outer surface of the bottom 6 is made in the form of a scattering (negative) optical element, then the distance from its surface to the front focus (front focal segment) bu is a negative value, i.e. the front focus of the outer surface of the bottom 6 will be behind it (along the rays).

This telescopic bottle acts like the bottle shown in FIG. 1, except that the rays 8 and 9 do not actually intersect with the optical axis 7 at point 10, but when they are refracted on the outer surface of the bottom 6, they again become parallel to axis 7 and form a direct (not inverted) magnified image.

FIG. 3 shows a telescopic bottle located horizontally, consisting of a body 1 and a screw connection of a lid 2 connected to it, containing liquid 3 and a certain amount of gas 4. The body 1 of a bottle is made of elastic material, and the neck has the ability to be pushed in along the optical axis. The bottom 5 of the housing 1 and the bottom 6 of the lid 2 of the bottle are made of transparent material in the form of collecting lenses, for which they are limited outside and inside by optical spherical surfaces, the symmetry axes of which coincide and form the optical axis 7. The distance along the axis 7 between the inner refracting surfaces of the bottom 5 and bottom 6 is equal to the sum of the rear focal segment of the first and front focal segment of the second.

This telescopic bottle acts like the bottle shown in FIG. 1, except that the rays 8 and 9 are refracted not only on the outer, but also on the inner surfaces of the bottom 5 and the bottom 6.

FIG. 4 shows a bottle similar to the bottle shown in FIG. 3, but empty (emptied) and containing only gas 4 (air). The neck of the bottle, together with the cap 2 of the indentation inside the body 1, is so much so that the distance along the axis 7 between the inner surfaces of the bottom 5 and the bottom 6 is equal to the sum of the corresponding focal lengths reduced in air. The exact alignment of the rear focus of the lens and the front focus of the eyepiece at point 10 (focusing) is performed in this case by unscrewing and screwing in the cover 2, which moves along the axis of the threaded connection, which coincides with the optical axis 7.

Industrial application

The possibility of industrial application of the present invention does not cause the applicant doubts. It can be used as a primitive and short-lived observation device or toy.

Claims (6)

1. A bottle containing a transparent liquid and a certain amount of gas, for example a carbonated drink, consisting of a body and a lid, the bottom part of the body made of transparent material and its transverse size (diameter) exceeds the transverse size (diameter) of the bottom part of the lid, also made of transparent material, characterized in that the bottom of the body and the bottom of the lid act, respectively, of the lens and eyepiece, and preferably when the bottle is not upright, together with the liquid contained in it They form a telescopic system, for which the bottom parts of the housing and the cover are at least partially and at least on one side (for example, externally) bounded by axisymmetric optical refractive surfaces (for example, spherical), and the symmetry axes of these surfaces coincide, forming the optical axis telescopic system, and the distance along the optical axis between the vertices of the nearest refracting surfaces of the bottom of the body and the lid is equal to the sum of the rear focal segment of the bottom of the lens body and the bottom focal segment of the bottom of the eyepiece cap. 2. The bottle according to claim 1, characterized in that the bottom of the body and the lid of the bottle are made of materials having refractive indices equal to the refractive index of the liquid contained in the bottle, while the axisymmetric optical refractive surfaces of the bottom of the body and the lid are limited only from the outside . 3. The bottle according to claim 1, characterized in that only one of the components acting as a lens and an eyepiece of the telescopic system (the bottom of the body or the bottom of the lid) is made of a material having a refractive index equal to the refractive index of the liquid contained in the bottle, and limited by an axisymmetric optical refractive surface only on the outside, and the other is made in the form of a lens and limited by axisymmetric optical refractive surfaces on both (external and internal) sides. 4. The bottle according to claim 1, characterized in that both the bottom part of the body and the bottom part of the lid are made in the form of lenses and are limited by axisymmetric optical refractive surfaces on both (outer and inner) sides. 5. The bottle according to claim 4, characterized in that the bottle body is made of an elastic material (for example, polymeric) and at least one of its parts containing a lens or connected with a part of a bottle containing a lens (for example, a neck with a cap), the possibility, after emptying the bottle, to penetrate into the housing along the optical axis by an amount sufficient to combine the back focus of the bottom of the lens body with the front focus of the bottom of the eyepiece cap and the formation of a telescopic system without liquid between the lens and the eyepiece m 6. A bottle according to any one of claims 1 to 5, characterized in that the bottle cap is connected to its body by means of a threaded connection, the axis of which coincides with the optical axis of the telescopic system, which makes it possible to focus the telescopic system by unscrewing and screwing the cap.