RU2162815C1 - Telescopic bottle - Google Patents

Abstract

FIELD: food industry; bottles for carbonated beverages. SUBSTANCE: bottle has housing 1, cap 2, transparent liquid 3 in bottle and gas 4. Housing has bottom 5, and cap 2 has bottom 6. Bottom are made of transparent material in form of lens and eye glass, respectively. to form, together with liquid, a telescopic system, when bottle is in non-vertical position. EFFECT: improved consumers' qualities of bottles, enlarged operating capabilities. 6 cl, 4 dwg

Description

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

 Glass bottles are known for storing food liquids (GOST 10117-91).

 The disadvantage of these bottles is that they can only be used for their intended purpose - to store liquid.

 From optics, telescopic systems are known that provide the ability to observe distant objects. Telescopic systems consist of two centered components - 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 for the operation of the telescopic system is such an arrangement of its components that the back focus of the lens (lens or refractive surface facing the observed object) coincides with the front focus of the eyepiece (lens or refractive surface facing the observer’s eye), for this, the distance between them along the optical axis (the distance between adjacent refractive surfaces of the lens and the eyepiece) should be equal to the sum of the rear and front focal segments of the lens and eyepiece, respectively. (Zakaznov N.P. et al. "Theory of Optical Systems", M., "Mechanical Engineering", 1992, p. 205).

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

 The technical result of the invention is to give the bottle the properties of an optical telescopic system.

 The aforementioned task is achieved in that the bottom parts of the body and the cap of the bottle act as the lens and eyepiece of the telescopic system and are made of transparent material bounded on the outside and on the inside (or only on the outside) by axisymmetric optical refractive surfaces (for example, spherical, surfaces of the second and highest orders, as well as planar) and so that the axis of symmetry of the refracting surfaces lie on one imaginary line, the so-called optical axis, and in order to rear focus lens coincides with the front focus of the eyepiece, the distance along the optical axis between the nearest (adjacent) the refracting surfaces of the bottom lens body and bottom cover-ocular equal to the sum of their respective front and back focal lengths. Since there is a liquid at the rear of the lens and in front of the eyepiece (i.e. between them) having a higher optical density than that of gas (air) outside the system, both the rear focal segment of the lens and the front focal segment of the eyepiece in a liquid medium will be larger than if there was gas between them. Therefore, the above-mentioned distance between the bottom of the lens body and the bottom of the eyepiece cap, which determines the axial size of the bottle, is composed of the corresponding focal segments for a liquid medium, the magnitude 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 case and the bottom bottle caps. When refracting the outer and inner surfaces of the bottom of the body and 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 lens system - the telescope. When only the outer surfaces of the bottom parts of the body and the bottle cover are made optical, 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 cap of the bottle (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 the liquid, the bottle usually contains some insignificant amount of free (undissolved) gas, the effect of the invention is possible only if the gas accumulation in the bottle is placed in such a way that it does not violate the optical continuity of the liquid in the region close to the optical axis and does not distort the course image forming optical rays as a result of their additional refraction at the interface of a liquid and a gas having a random shape. The simplest way to achieve this is to place the bottle in a horizontal position, when gas accumulates in the very top of the bottle’s volume near its wall and does not affect the course of the rays.

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

 The technical result of the invention can be achieved with different designs 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 scheme; in the form of a collecting (lens) and scattering (eyepiece) lenses - according to the Galilean telescope scheme, in the form of convex surfaces of a biconvex telescopic lens; in the form of convex and concave surfaces of a convex-concave 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 a technical result of the invention.

 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 back focus of the bottom of the lens body and the front focus of the bottom of the eyepiece cap, which is violated after emptying the bottle due to the corresponding focal segments of the lens and eyepiece having decreased in the gas environment, is done by pressing or denting one part of the bottle body containing the lens (for example, the neck with lid), to another part of the body in the direction (along) the optical axis. In this case, the bottle body is made of an elastic material (for example, polymeric). Accurate focusing (focusing) in this and other cases can be done by unscrewing and screwing the cover connected to the housing by a threaded connection, the axis of which coincides with the optical axis of the telescopic system.

 The essence of the invention is illustrated in FIG. 1-4.

 In FIG. 1 shows a telescopic bottle located horizontally, consisting of a body 1 and a threaded connection of a cap 2 connected to it, containing a liquid 3 and a certain amount of gas 4. The bottom 5 of the body 1 and the bottom 6 of the bottle cap 2 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 bottom 6 are bounded by optical spherical surfaces whose symmetry axes 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, acting as the objective of the telescopic system, and the outer surface of the bottom 6, acting as an eyepiece, are convex outward. The distance along axis 7 between the outer 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 operates as follows. When the bottle is in a horizontal position, gas 4 accumulates in the uppermost part of the volume of the bottle and does not affect the course of the image-forming optical rays 8 and 9 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 back focus of the outer surface of the bottom 5 and the front focus of the outer surface of the bottom 6 and located at a distance equal to their respective focal segments. Having passed 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 enlarged image.

 In FIG. 2 shows a telescopic bottle located horizontally, consisting of a housing 1 and a threaded connection of a cover 2 connected to it, containing a liquid 3 and a certain amount of gas 4. The bottom 5 of the housing 1 and the bottom 6 of the bottle cover 2 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 bottom 6 are bounded by optical spherical surfaces whose symmetry axes 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 acts as the objective of the telescopic system, is convex outward, the outer surface of the bottom 6, which acts as an eyepiece, is made concave inward. The distance along axis 7 between the outer 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, but since the outer surface of the bottom 6 is made in the form of a negative (scattering) optical element, the distance from its surface to the front focus ( the front focal segment) will be 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, having refracted on the outer surface of the bottom 6, again become parallel to axis 7 and form a straight line (not inverted) enlarged image.

 In FIG. 3 shows a telescopic bottle arranged horizontally, consisting of a housing 1 and a threaded connection of a cover 2 connected to it, containing a liquid 3 and a certain amount of gas 4. The bottle body 1 is made of elastic material, the neck being able to bend inward along the optical axis. The bottom 5 of the housing 1 and the bottom 6 of the bottle cap 2 are made of a transparent material in the form of collecting lenses, for which they are bounded on the outside and inside by optical spherical surfaces whose symmetry axes coincide and form the optical axis 7. The distance along axis 7 between the internal refractive surfaces bottom 5 and bottom 6 is equal to the sum of the back focal segment of the first and front focal segment of the second.

 This telescopic bottle acts like the bottle of 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 bottom 6.

 In FIG. 4 shows a bottle similar to the bottle of FIG. 3, but empty (empty) and containing only gas 4 (air). The neck of the bottle, together with the cap 2, is dented into the body 1 so much that the distance along the axis 7 between the inner surfaces of the bottom 5 and bottom 6 is equal to the sum of the corresponding focal segments decreased in the air. The exact combination of the back focus of the lens and the front focus of the eyepiece at point 10 (focusing) is made in this case by unscrewing and screwing the cover 2, moving along the axis of the threaded connection, coinciding with the optical axis 7.

 Analogs of the invention to the author are not known. The possibility of industrial application of the invention does not cause doubt in the author.

Claims (6)

 1. A bottle containing a clear liquid and a certain amount of gas, for example, a carbonated drink consisting of a body and a lid, the bottom of the body made of transparent material and its transverse size (diameter) exceeds the transverse size (diameter) of the bottom of the lid, also made of transparent material, characterized in that the bottom of the body and the bottom of the cap serve, respectively, of the lens and eyepiece, and when the bottle is not vertical, together with the liquid contained in it form a telescopic system, for which each The dye is bounded at least on one side (external or internal) by an axisymmetric optical refractive surface (for example, spherical), and the axis of symmetry of the said surfaces coincide, forming the optical axis, and the distance along the optical axis between the nearest refracting surfaces of the bottom of the lens body and the bottom of the cap eyepiece is equal to the sum of the posterior focal segment of the first and anterior focal segment of the second.  2. The bottle according to claim 1, characterized in that the bottom of the body and the bottom of the bottle cap are made of materials having refractive indices equal to the refractive index of the liquid contained in the bottle, while axisymmetric optical refractive surfaces of the bottom of the body and the bottom of the lid are limited only from the outside.  3. The bottle according to claim 1, characterized in that one bottom (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 is limited by an axisymmetric optical refractive surface only from the outside, and the other the bottom is made in the form of a lens and is limited by axisymmetric optical refractive surfaces on both (outer and inner) sides.  4. The bottle according to claim 1, characterized in that the bottom of the body and the bottom of the lid are made in the form of lenses and are limited by axisymmetric optical refractive surfaces from the outside and from the inside.  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) after emptying the bottle, creep into the body 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.  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 system, which makes it possible to focus the telescopic system by unscrewing and screwing the cap.

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