CZ30492U1 - A vessel with a flexible element - Google Patents

Abstract

Present invention relates to a container with flexible element containing a pressurised container, spring, collecting tube and top, wherein the flexible element (2) is connected to the pressurised container (1), in which the flexible element (2) is formed by a base (26) and body (22), or is formed by a base (26) and spring (21), of by a base (26) and body (22) containing a spring (21), in which the base (26), body (22) and spring (21) adjoin to the inner walls of the pressurised container (1), and/or the flexible element (2) is furnished with at least one sealing element (33), which is inserted at the edges of the base (26) for preventing the penetration of liquid above or below the base (26), in which the body (22) of the flexible element (2) is made of a material with memory and/or rubber and/or plastic and/or textile, and the pressurised container (1) also contains a head (29), in which the head (29) of the flexible element (2) or pressurised container (1) is furnished with a securing top (25) and a catch (27) created in the base (26) of the flexible element (2) in order to secure the position of the base (26), in which the head (29) further contains a hole (251) for inserting the securing top (251) or stopper (30), in which the head (29) of the flexible element (2) or pressurised container (1) contains an outlet hole (231) with a neck (23) and release valve (24) controlled by a lever (241) and spring (242).

Description

The technical solution relates to a special modification of any closed container, consisting in the fact that a flexible element is installed in the inner space of the container. As a resilient element, it is possible to use a spring or other shape-memory material, such as plastic, rubber, etc., which can exert pressure after compression or stretching.

In the event that the resilient element changes its shape from the initial, i.e. resting, position, it thus begins to act on the contents of the container, which is usually a gas or liquid, and thus creates an overpressure in the inner space of the container. By pressing the flexible element, it is then possible to push the contents of the container into the outer space via a suitable valve. The resilient element may be in direct contact with the inner contents of the container or may be separated from it via a suitable membrane or seal.

Prior art

Currently, there are several solutions for pressure vessels, which work mainly on the principle of compressed gas. Mechanically, it is then also possible to use a movable piston inside the vessel based on the principles of hydraulics.

The disadvantage of such a solution is the need to fill the pressure vessel with compressed gas after each emptying or the need for a complex hydraulic piston mechanism with appropriate sealing elements.

There is no pressure vessel available on the market that the user can easily fill himself and create a permanent overpressure in it without the use of other gases, liquids or complex mechanisms. The solution is especially useful in the field of common small beverage bottles or as a part of sprayers, etc.

Especially in the field of sports, eg when running, conventional bottles have the disadvantage that the fluid moves and splashes in them. In addition to the unpleasant sound effect, there is a constant change in the center of gravity of the entire bottle, and the athlete must balance it with his hand. Another disadvantage of today's standard sports bottles is that the user usually has to suck fluid, which disrupts his breathing rhythm. The advantage is also that the water from the bottle sprays under pressure, and therefore it is not necessary to tilt your head when drinking. It is also possible at any time and at any position of the bottle to accurately determine the residual amount of liquid in the container.

The essence of the technical solution

The essence of the technical solution is a closed pressure vessel provided with at least one built-in flexible element. Hereinafter, a pressure vessel is the part of the vessel into which the resilient element is inserted. The fastening of the flexible element to the pressure vessel is solved by the usual suitable ways of ensuring sufficient pressure and tightness, eg by a screw thread, a lever closure, etc. To ensure the functionality of the pressure vessel according to this solution, it is not decisive whether the thread is formed on the outside or inside of the pressure vessel, but in view of the thread clogging limitation it is of course advantageous for the thread to be formed on the outer wall of the pressure vessel.

The body of the flexible element can exert pressure on the inner walls and the contents of the pressure vessel, or on the inner walls resp. the volume of the elastic element itself.

If the designation "cylinder" is used in this description, then it is the final product, i.e. the combination of the pressure vessel with the flexible element described in this technical solution.

The body of the resilient element copies the inner walls of the vessel and, by expansion, reduces the inner space of the pressure vessel. By its expansion, the resilient element gradually forms essentially a memory vessel of varying volume, which compresses the contents of the pressure vessel in the desired direction through the outer walls. The term "memory" in this case means that the resilient element is made of a suitable material which remembers its initial shape, to which it tries to return spontaneously, when no external forces act on it. The resilient element, which is essentially an elastic memory structure,

-1 CZ 30492 The UI then forms a separate closed vessel or can separate the internal volume (medium) of the pressure vessel from itself, while it is capable of expansion and contraction inside the pressure vessel, as can be seen from the attached figures.

In a variant embodiment of this technical solution, the part of the resilient element intended for attaching the resilient element to the pressure vessel is formed by the head of the resilient element provided with a thread for attaching the resilient element to the cylinder. The head of the resilient member further includes a drain valve comprising a lever and a spring. The spring is any element capable of compressing and returning to the original shape after the release of pressure caused by the displacement of the discharge valve. The head of the resilient element further comprises an outlet and preferably also a neck. The neck of the head of the flexible element allowing comfortable drinking of the liquid is not a necessary element for the functionality of this solution and can be replaced by other suitable equivalents, such as a drinking hose, etc. The head of the resilient element preferably also comprises a locking cap of the resilient element to secure the body of the resilient element in a compressed shape when the body of the resilient element is expanded at rest. For this purpose, the body of the resilient element is preferably provided with a safety catch. The body of the resilient element also preferably comprises a bottom formed of a solid material ensuring an efficient expulsion of liquid from the space under the body of the resilient element towards the collecting tube. This solution is shown, for example, in FIGS. 3a to 3q. The body and the bottom of the resilient element comprise a recess in the shape of a collecting tube, as can be seen, for example, in FIG. 3f. In another embodiment, the liquid may be forced directly into the outlet of the pressure vessel.

The walls of the body of the elastic element are formed, for example, by springs inserted or encapsulated in a plastic housing, a rubber balloon, a plastic piston, etc. This technical solution includes various embodiments of the body of the resilient element, which, when different in physical design, perform the same function described above. These embodiments are further described in more detail in the examples and illustrated in the accompanying figures.

The technical solution shown in FIG. 1a to 1q consists of a pressure vessel provided with an external thread for fixing a resilient element. The body of the resilient element in this case is formed by a spring which is encapsulated in a plastic housing. The body and the bottom of the resilient element comprise a recess in the shape of a collecting tube, as can be seen, for example, from FIG. Ih.

The walls of the flexible element copy the shape of the inner wall of the pressure vessel. The spring is stretched in the rest state, i.e. expanded here, and after compression it acts as a compression spring. The plastic housing of the resilient element is resilient in a membrane shape to allow the spring to expand and compress, but at the same time form a separate closed container together with the spring.

If the body of the elastic element is shrunk at rest, then we also talk about its contraction, resp. contracted state. Otherwise, ie if it is stretched in the rest state, ie expanded, then when putting it into a compressed or contracted state, we also talk about its compression, ie compression.

In one embodiment of the memory container, the resilient element is in an expanded shape at rest, the contraction of which creates a pressure later released by its outer walls, resp. in other words, the walls of the memory vessel, to the interior of the pressure vessel. For example, the aforementioned fuse can be used to secure the resilient element in a compressed shape.

In another embodiment of the memory container, the resilient element is formed in an inverse form, i.e. the resilient element is contracted or shrunk at rest. This solution is shown in Figs. 2a to 2p or Figs. 4a to 4p. To secure the resilient element in the expanded state, a locking cap, for example, can serve as a safety device. In this case, the resilient element must first be stretched, ie converted into an extension state, secured with a safety device and filled with fluid. For example, a guide pin inserted into the outer wall of the body of the resilient element and moving in a guide groove formed in the wall of the pressure vessel can be used for stretching, as can be seen, for example, from Figures 2e, 2f, 2k, 21, 4e, 4f, 4k and 41. In a preferred embodiment, the solution comprises at least one pair of guide pins and one pair of guide grooves for evenly distributing the force required to stretch the body of the resilient element. In this case, the inner walls of the resilient element serve to retain fluid. In this embodiment, the opening in the neck of the head of the resilient element is provided with a closure instead of a locking cap, which in this embodiment is formed in the bottom of the pressure vessel, as is further apparent from the accompanying figures. Stretching springs

However, the UI of the elastic element can also be realized in other suitable ways, for example by a rope / cord attached to the bottom of the elastic element.

In a variant embodiment of the memory container according to FIGS. 5a to 50o and 6a to 6p, the resilient element is designed such that the fluid is expelled by the resilient element from the bottom of the container, respectively. the fastening of the resilient element is performed at the opposite end of the pressure vessel to the location of the discharge valve, which, in contrast to the solutions described above, is part of the pressure vessel and is therefore not formed on the head of the resilient element. This solution also does not include a collecting tube, as it is superfluous.

The solutions described above can be applied to any closed container, eg drinking bottles, containers for various cleaning and chemical agents, sprays, cosmetics, etc.

In a preferred embodiment, a gas, in particular air, e.g. compressed air can be injected into the interior of the memory container, i.e. the body of the resilient element, and by increasing the pressure in the interior of the resilient element body the expansion effect of the resilient element body can be increased . It is therefore a combination of the mechanical principle and the principle of extrusion of liquid by overpressure. The tensile or compressive force of the body of the resilient element is dimensioned in the manufacture of the entire cylinder with regard to the requirements of use, i.e. mainly how strong the flow, i.e. the high flow, is desirable to expel fluid from the interior of the cylinder.

It is not clear what materials the pressure vessel or flexible element is made of. The choice of suitable materials depends mainly on the medium that the bottle should store.

As basic construction materials of the pressure vessel according to this technical solution it is possible to use, according to the requirements for the internal medium:

- metals and their alloys, eg stainless steel, aluminum, etc.

- plastics

- hardened rubber or silicone

- glass

- wood

As the basic construction materials of the expansion body, ie the flexible element, it is possible to use, according to the requirements for the internal medium (chemicals, contact with food, contact with drinking water), eg:

- metal springs in plastic, textile or rubber housings

- plastic springs in plastic, textile or rubber housings

- flexible rubber bushes

- flexible plastic housings

- flexible textile fibers (impermeable)

The resilient element can be, for example, a spring with a housing or a spring with a seal or a rubber housing or a housing with a memory function.

In Example 6, the bottom of the resilient element is provided on the sides with a seal which, when inserted into the container, seals circumferentially to the wall of the container, so it is not necessary for the resilient element to comprise a housing.

Explanation of drawings

Giant. 1a shows a pressure vessel according to this technical solution according to variant A with a section plane A marked;

Giant. 1b shows a pressure vessel according to this technical solution according to variant A with a section plane B marked;

Giant. 1c shows a section A-A of a pressure vessel according to variant A with a compressed resilient element;

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Giant. Id shows a section A-A of a pressure vessel according to variant A with an expanded resilient element,

Giant. 1e shows a section B-B of a pressure vessel according to variant A with a compressed resilient element;

Giant. 1f shows a section B-B of a pressure vessel according to variant A with an expanded resilient element;

Giant. Ig shows separately a pressure vessel with a collecting tube with a marked section E and a section of the pressure vessel E-E;

Giant. 1h shows a separately resilient element with a spring with a marked section F and a section of the resilient element F-F;

Giant. 11 shows a separately compressed resilient element according to variant A;

Giant. Ij shows a separately compressed resilient element according to variant A with a locking cap;

Giant. 1k shows a pressure vessel filled with liquid;

Giant. 11 shows a resilient element according to variant A with an indication of the direction of contraction;

Giant. 1m shows a separately compressed resilient element according to variant A;

Giant. In shows a method of placing a compressed resilient element in a pressure vessel filled with liquid;

Giant. 10 shows a compressed resilient element according to variant A placed in a pressure vessel filled with liquid with a locking cap connected;

Giant. Ip shows a compressed resilient element according to variant A stored in a pressure vessel filled with a liquid released locking cap;

Giant. Iq shows an expanded resilient element according to variant A with an indication of the flow of liquid from the pressure vessel;

Giant. 2a shows a pressure vessel according to this technical solution according to variant B with a section plane A marked;

Giant. 2b shows a pressure vessel according to this technical solution according to variant B with a section plane B marked;

Giant. 2c shows a section A-A of a pressure vessel according to variant B with a contracted resilient element;

Giant. 2d shows a section A-A of a pressure vessel according to variant B with an expanded resilient element;

Giant. 2e shows a section B-B of a pressure vessel according to variant B with a contracted resilient element;

Giant. 2f shows a section B-B of a pressure vessel according to variant B with an expanded resilient element;

Giant. 2g shows separately a pressure vessel without a collecting tube with a guide groove and a marked section E and a section of the pressure vessel E-E;

Giant. 2h shows a separately contracted resilient element according to variant B;

Giant. 2i shows a separately expanded resilient element according to variant B;

Giant. 2j shows a contracted resilient element according to variant B, with an indication of storage in a pressure vessel;

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Giant. 2k shows a pressure vessel according to variant B with a contracted resilient element with an indication of the engagement of the guide pin;

Giant. 21 shows a pressure vessel according to variant B with an expanded resilient element, showing the engagement of the locking cap;

Giant. 2m shows a pressure vessel according to variant B with an expanded resilient element filled with fluid;

Giant. 2n shows a pressure vessel according to variant B with an expanded resilient element filled with fluid, indicating the location of the closure;

Giant. 2o shows a pressure vessel according to variant B with an expanded resilient element filled with fluid, indicating the release of the locking cap;

Giant. 2p shows a pressure vessel according to variant B, with an indication of the compression of the elastic element partially filled with fluid and with an indication of the expulsion of the liquid from the vessel;

Giant. 3a shows a pressure vessel according to this technical solution according to variant C with a section plane A marked;

Giant. 3b shows a pressure vessel according to this technical solution according to variant C with a section plane B marked;

Giant. 3c shows a section A-A of a pressure vessel according to variant C with a compressed resilient element;

Giant. 3d shows a section A-A of a pressure vessel according to variant C with an expanded resilient element;

Giant. 3e shows a section B-B of a pressure vessel according to variant C with a compressed resilient element;

Giant. 3f shows a section B-B of a pressure vessel according to variant C with an expanded resilient element;

Giant. 3g shows separately a pressure vessel with a collecting tube with a marked section E and a section of the pressure vessel E-E;

Giant. 3h shows a separately compressed resilient element according to variant C;

Giant. 3i shows a separately compressed resilient element according to variant C, with an indication of the mounting of the locking cap;

Giant. 3j shows a separately expanded resilient element according to variant C with a locking cap in place and a section of the resilient element;

Giant. 3k shows separately a pressure vessel filled with liquid;

Giant. 31 shows a separately expanded resilient element according to variant C;

Giant. 3m shows a separately compressed resilient element according to variant C;

Giant. 3n shows a method of placing a compressed resilient element according to variant C in a pressure vessel filled with liquid;

Giant. 30 shows a compressed resilient element according to variant C stored in a pressure vessel filled with liquid;

Giant. 3p shows a compressed resilient element according to variant C placed in a pressure vessel filled with liquid and indicating the release of the locking cap and the direction of discharge of the liquid;

Giant. 3q shows an expanded resilient element according to variant C with the indication of the discharge of the liquid from the pressure vessel;

Giant. 4a shows a pressure vessel according to this technical solution according to variant D with a section plane A marked;

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Giant. 4b shows a pressure vessel according to this technical solution according to variant D with a section plane B marked;

Giant. 4c shows a section A-A of a pressure vessel according to variant D with a contracted resilient element;

Giant. 4d shows a section A-A of a pressure vessel according to variant D with an expanded resilient element;

Giant. 4e shows a section B-B of a pressure vessel according to variant D with a contracted resilient element;

Giant. 4f shows a section B-B of a pressure vessel according to variant D with an expanded resilient element;

Giant. 4g shows separately a pressure vessel without a collecting tube with a guide groove and a marked section E and a section of the pressure vessel E-E;

Giant. 4h shows a separately contracted resilient element according to variant D;

Giant. 4i shows a separately expanded resilient element according to variant D;

Giant. 4j shows a contracted resilient element according to variant D with the indication of being placed in a pressure vessel;

Giant. 4k shows a pressure vessel according to variant D with a contracted resilient element with an indication of the engagement of the guide pin;

Giant. 41 shows a pressure vessel according to variant D with an expanded resilient element, indicating the engagement of the locking cap;

Giant. 4m shows a pressure vessel according to variant D with an expanded flexible element filled with fluid;

Giant. 4n shows a pressure vessel according to variant D with an expanded resilient element filled with fluid, indicating the location of the closure;

Giant. 4o shows a pressure vessel according to variant D with an expanded resilient element filled with fluid, indicating the release of the locking cap;

Giant. 4p shows a pressure vessel according to variant D, indicating the contraction of the resilient element partially filled with fluid and indicating the expulsion of liquid from the vessel;

Giant. 5a shows a pressure vessel according to this technical solution according to variant E with a section plane A marked;

Giant. 5b shows a pressure vessel in accordance with this technical solution according to variant E with the section plane B marked;

Giant. 5c shows a section A-A of a pressure vessel according to variant E with a compressed resilient element;

Giant. 5d shows a section A-A of a pressure vessel according to variant E with an expanded resilient element;

Giant. 5e shows a section B-B of a pressure vessel according to variant E with a compressed resilient element;

Giant. 5f shows a section B-B of a pressure vessel according to variant E with an expanded resilient element;

Giant. 5g shows separately a pressure vessel with a drain valve, a lever and a spring formed in the lower part of the pressure vessel;

Giant. 5h shows a separately compressed resilient element according to variant E;

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Giant. 5i shows a separately expanded resilient element according to variant E with an indication of the direction of expansion;

Giant. 5j shows separately a pressure vessel with a drain valve, a lever and a spring formed in the lower part of the pressure vessel filled with fluid;

Giant. 5k shows a separately resilient element with an indication of the direction of contraction;

Giant. 51 shows a pressure vessel according to variant E with a compressed resilient element, indicating the engagement of the locking cap;

Giant. 5m shows a pressure vessel according to variant E with a compressed resilient element, indicating the connection to a pressure vessel filled with fluid;

Giant. 5n shows a pressure vessel according to variant E with a compressed resilient element and a pressure vessel filled with fluid, indicating the release of the locking cap and the expansion of the resilient element;

Giant. 5o shows a pressure vessel according to variant E with an expanded resilient element and an indication of the discharge of liquid from the vessel;

Giant. 6a shows a pressure vessel according to this technical solution according to variant F with a section plane A marked;

Giant. 6b shows a pressure vessel according to this technical solution according to variant F with a section plane B marked;

Giant. 6c shows a section A-A of a pressure vessel according to variant F with a compressed resilient element;

Giant. 6d shows a section A-A of a pressure vessel according to variant F with an expanded resilient element;

Giant. 6e shows a section B-B of a pressure vessel according to variant F with a compressed resilient element;

Giant. 6f shows a section B-B of a pressure vessel according to variant F with an expanded resilient element;

Giant. 6g shows separately a pressure vessel with a drain valve, a lever and a spring formed in the lower part of the pressure vessel;

Giant. 6h shows a separately compressed resilient element according to variant F, showing the engagement of the locking cap;

Giant. 6i shows a separately expanded resilient element according to variant F;

Giant. 6j shows separately a pressure vessel with a drain valve, a lever and a spring formed in the lower part of the pressure vessel filled with fluid;

Giant. 6k shows a separately resilient element with an indication of the direction of contraction;

Giant. 61 shows a separately resilient element with an indication of the engagement of the locking cap;

Giant. 6m shows a pressure vessel according to variant F with a compressed resilient element, showing the connection to a pressure vessel filled with fluid;

Giant. 6n shows a pressure vessel according to variant F with a compressed resilient element and a pressure vessel filled with fluid;

Giant. 6o shows a pressure vessel according to variant F, indicating the release of the locking cap and the expansion of the resilient element;

Giant. 6p shows a pressure vessel according to variant F, with the liquid being expelled from the vessel;

Giant. 7a shows a pressure vessel according to this technical solution according to variant G with a section plane A marked;

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Giant. 7b shows a pressure vessel according to this technical solution according to variant G with a section plane B marked;

Giant. 7c shows a section A-A of a pressure vessel according to variant G with a compressed resilient element;

Giant. 7d shows a section A-A of a pressure vessel according to variant G with an expanded resilient element;

Giant. 7e shows a section B-B of a pressure vessel according to variant G with a compressed resilient element;

Giant. 7f shows a section B-B of a pressure vessel according to variant G with an expanded resilient element;

Giant. 7g shows separately a pressure vessel with a drain valve, a lever and a spring formed in the lower part of the pressure vessel;

Giant. 7h shows a separately compressed resilient element according to variant G provided with a bridging of the fluid flow in the head of the resilient element for draining the liquid into the collecting tube of the pressure vessel;

Giant. 7i shows the separately compressed resilient element according to FIG. 7h rotated by 90 degrees;

Giant. 7j shows a separately expanded resilient element according to variant G;

Giant. 7k shows a pressure vessel according to variant G with a compressed resilient element provided with a fluid flow bridge, indicating the connection of the resilient element to an empty pressure vessel;

Giant. 71 shows a pressure vessel according to variant G with an expanded resilient element filled with fluid, indicating the engagement of the locking cap;

Giant. 7m shows a pressure vessel according to variant G with a resilient element displacing fluid;

Giant. 8 shows schematically typical embodiments of a pressure vessel with sealing elements to ensure the impermeability of fluid to the inner or outer space of the resilient element, the arrow indicating whether the resilient element is push or pull;

Giant. 9 shows schematically typical embodiments of a pressure vessel without sealing elements, the arrow determining whether the resilient element is push or pull;

Examples of technical solution

Example 1

Variant A

The technical solution shown in FIG. 1a to 1q consists of a pressure vessel 1 provided with an external thread 11 for fixing the resilient element 2. The resilient element 2 is formed by a spring 21 which is encapsulated in a plastic housing which forms the walls of the body 22 of the resilient element 2. the shape of the inner wall of the pressure vessel 1. The spring 21 is stretched in the rest state, i.e. in the expanded state, and after compression it acts as a compression spring. The plastic housing forming the body 22 of the resilient element 2 is a resilient membrane provided with springs 21 at the point of membrane breakage to allow the spring to expand and contract, but at the same time form a separate container together with the spring. The lower part of the resilient element is terminated by a fixed bottom 26, to the inner wall of which an inwardly connected fuse 27 is connected in connection with a locking cap 25 to secure the resilient element in a compressed state.

Part of the elastic element 2 in the upper part is:

- a head 29 with an internal thread 28 for attaching the resilient element 2 to the cylinder 1;

- a drain valve 24 provided with a lever 241 and a spring 242;

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- a locking cap 25 of the resilient element housed in the opening 251;

- a neck 23 of a resilient element with an outlet 231;

A part of the pressure vessel is a collecting tube 12 serving to supply fluid from the bottom 26 of the flexible element 2 to the outlet 231 in the neck 23 of the flexible element 2. Fig. 1h shows a recess 221 of the body 22 of the flexible element and the bottom 26 in the form of a collecting tube 12. bypasses the collecting tube 12.

The use of a pressure vessel according to this variant solution consists in first filling the pressure vessel with the required fluid. Flexible element 2, resp. its resilient body 22 is compressed (converted from the expanded state to the compressed state) and the spring pressure is secured by a locking cap 25 which secures the position of the lock 27 formed in the lower part of the resilient element. Subsequently, the resilient element is screwed onto the filled cylinder and the spring pressure is released by turning the locking cap 25. This creates a permanent pressure on the internal volume of the container. Via the drain valve 24, it is then possible to drain the liquid from the vessel under pressure into the outer space.

Example 2

Option B

The technical solution shown in FIG. 2a to 2p consists of a pressure vessel 1 with an external thread 11 in the upper open part. The resilient element 2 is made of a resilient material, in this case rubber, which together with the head 29 of the resilient element and the lower bottom 26 also forms a separate closed container. The rubber diaphragm shrinks at rest and forms a so-called pull piston after stretching. The rubber membrane is flexible enough to be able to expand and contract.

Part of the elastic element 2 in the upper part is:

- a head 29 with an internal thread 28 for attaching the resilient element 2 to the cylinder 1;

- a closure 30 with an opening 251 for impregnation of the resilient element 2;

- a drain valve 24 provided with a lever 241 and a spring 242;

- a neck 23 of a resilient element with an outlet 231;

The resilient element 2 is provided in the lower part with a safety device 27, which after turning the locking cap 25 connected to the bottom wall of the pressure vessel 1 allows to secure the resilient element 2 in the stretched state.

At least one guide groove 31 formed in the wall of the pressure vessel 1 and at least one guide pin 32 running in the guide groove 31 serve to stretch the resilient element 2.

The use of a cylinder according to this variant solution consists in that first the resilient element 2 is stretched after engagement of the guide pin 32, preferably a pair of guide pins 32, and is filled with the desired fluid through the opening 251. The fluid and pressure exerted by the rubber membrane forming the side wall 22 of the resilient element 2 is secured in the interior of the resilient element 2 by screwing on the filling cap 30. The resilient element 2 thus filled is inserted into the pressure vessel 1 and screwed onto the thread 11 of the pressure vessel 1. Via the drain valve 24, it is then possible to drain the fluid under pressure into the outer space. .

Example 3

Variant C

The technical solution shown in FIG. 3a to 3q is essentially the same as variant A described in Example 1, except that the body 22 of the resilient element is made of a resilient membrane-shaped plastic material with a memory function which is expanded at rest.

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Example 4

Option D

The technical solution shown in FIG. 4a to 4p is essentially a combination of variant A and variant B described in Examples 1 and 2, the body of the resilient element 2 being made of the same material as in Example 1, but shrinking at rest after the example of Example 2.

Example 5

Option E

The technical solution shown in FIG. 5a to 5o is based on variant A, but the difference from variant A is that the discharge elements, i.e. the neck 23 of the flexible element with the outlet 231 and the discharge valve 24 provided with the lever 241 and the spring 242, are formed at the bottom of the pressure vessel 1. instead of being formed on the head 29 of the resilient element 2. The head 29 of the resilient element thus comprises only a thread 28 and an opening 251 for accommodating the locking cap 25.

The use of the pressure vessel according to this variant solution consists, as in Example 1, in that the pressure bottle 1 is first filled with the desired fluid. The body 22 of the resilient element is compressed (converted from the expanded state to the compressed state) and the spring pressure is secured by a locking cap 25 which secures the position of the lock 27 formed in the lower part of the resilient element. Subsequently, the resilient element is screwed onto the filled cylinder and the spring pressure is released by rotating the locking cap 25, as can be seen in FIG. 5n.

Example 6

Variant F

The technical solution shown in FIG. 6a to 6p is substantially identical to the variant E described in Example 5, except that the body of the resilient element 2 is formed of an open spring 21 which is expanded at rest. The bottom 26 of the resilient element comprises, in contact with the wall of the pressure vessel, sealing elements 33 to ensure the impermeability of the fluid to the structure of the spring 21.

Example 7

Variant G

The technical solution shown in FIG. 7a to 7m is essentially a combination of variant B described in Example 2 and variant E described in Example 5, with the bottom 26 of the resilient element being provided with a safety device 27 to ensure fluid impermeability outside the body 22 of the resilient element. a locking cap 25 over the head 29 of the resilient element 2. Fluid may be expelled by bridging 34 the fluid flow formed in the head 29 of the resilient element to drain fluid into the collection vessel 12 of the pressure vessel, as seen in Figures 7m and 71.

Industrial applicability

The technical solution can be used for personal use as a means of replenishing fluids, especially for athletes, also for drivers of motor vehicles, where the bottle does not obstruct the view when drinking, but this solution is usable wherever there is a need to create a permanent overpressure in the container without the use of other gases, liquids or complex mechanisms.

Claims (6)

CLAIMS FOR PROTECTION A container with a resilient element, comprising a pressure vessel, a spring, a collecting tube and a lid, characterized in that the resilient element (2) is connected to the pressure vessel (1), the resilient element (2) being formed by a bottom (26) and body (22), or is formed by a bottom (26) and a spring (21), or is formed by a bottom (26) and a body (22) comprising a spring (21), wherein the bottom (26), the body (22) and the spring (21) abut the inner walls of the pressure vessel (1), and / or the resilient element (2) is provided -10CZ 30492 UI by at least one sealing element (33) which is placed at the edges of the bottom (26) to prevent the penetration of liquid below or above the bottom (26), the body (22) of the resilient element (2) being made of a memory material and / or or rubber and / or plastic and / or fabric, and furthermore the pressure vessel (1) comprises a head (29), the head (29) of the resilient element (2) or the pressure vessel (1) being provided with a locking cap (25) and a safety device ( 27) formed in the bottom (26) of the resilient element (2) to secure the position of the bottom (26), the head (29) further comprising an opening (251) for receiving a locking cap (251) or a closure (30), the head (29) of the resilient element (2) or the pressure vessel (1) comprises an outlet (231) with a neck (23) and a drain valve (24) operated by a lever (241) and a spring (242). Container with a resilient element according to claim 1, characterized in that the inner wall of the pressure vessel (1) comprises a collecting tube (12) for draining fluid into the outlet opening (231). Container with a resilient element according to one of Claims 1 to 2, characterized in that the pressure vessel (1) is provided with a cable or rope or at least one guide groove (31) for stretching the resilient element (2) and the resilient element (2) is fitted at least one guide pin (32) slidable along the entire length of the guide groove (31). Container with a flexible element according to one of Claims 1 to 3, characterized in that the flexible element (2) is connected to the pressure vessel (1) by means of a lever closure or by means of a thread (11) on the outer wall of the pressure vessel (1) and the thread (). 28) on the inner wall of the head (29) of the resilient element (2). Container with a resilient element according to one of Claims 1 to 4, characterized in that the head (29) of the resilient element comprises a bridge (34) for directing the flow of fluid into the pressure vessel (1). Container with a flexible element according to one of Claims 1 to 5, characterized in that it comprises a pump and / or a piston for injecting gas into the interior of the pressure vessel (1) or the flexible element (2) to increase the expansion effect of the flexible element (2).