RU214525U1 - Cellar - Google Patents

Abstract

The utility model relates to the field of construction, namely to underground structures for food storage. Cellar, including a hollow body with an inlet for user access inside the body, the body consists of two end modules and an intermediate module located between the end modules, each module contains a load-bearing frame formed from interconnected profiles oriented in three planes, over the load-bearing frame a plastic sheathing was installed to form the module capacity; each end module contains an opening, and the intermediate module contains two openings, providing the possibility of combining the containers of the end modules and the intermediate module into a single container, adjacent modules are interconnected. The technical result achieved as a result of solving the problem is to expand the arsenal of funds for the construction of cellars. An additional technical result is to increase the stability of the cellar to the external pressure of the soil. 22 w.p. f-ly, 2 ill.

Description

The utility model relates to the field of construction, namely to underground structures for food storage.

State of the art

From the prior art known various designs of tanks, providing the possibility of underground placement.

In particular, from the patent for the invention of the Russian Federation No. 2768051 (published on March 23, 2022), a modular tank is known, including a hollow body with a neck, made of a polymer material and consisting of interconnected hollow modules. At the same time, the body modules are hermetically connected to each other by end parts by preliminary tightening with bolts and nuts through their aligned through holes in the ledges, as well as by a continuous seam of plastic melt, made from the inside and outside.

The disadvantage of the known solution is the low strength and low resistance to external ground pressure, which does not allow the use of this design as a cellar. At the same time, in tanks, this problem is solved directly by filling the inner container with liquid by 50% or more, which is unacceptable for a cellar.

The objective of the claimed utility model is to develop a cellar design that provides increased resistance to external soil pressure, as well as expanding the arsenal of tools for building cellars.

Disclosure

The technical result in the proposed cellar is achieved in that the cellar includes a hollow body with an inlet for user access to the inside of the body, the body consists of two end modules and an intermediate module located between the end modules, each module contains a supporting frame formed from interconnected profiles , oriented in three planes, a plastic sheathing is installed on top of the supporting frame to form a module capacity; each end module contains an opening, and the intermediate module contains two openings, providing the possibility of combining the containers of the end modules and the intermediate module into a single container, adjacent modules are interconnected.

Possible clarifying features of the claimed utility model are listed below.

The end module has the shape of a hemisphere, while the carrier frame contains vertical, horizontal, radial and annular profiles interconnected to form a carrier frame in the form of a hemisphere.

The end module has the shape of a cylinder, while the supporting frame contains vertical, horizontal and annular profiles interconnected to form a supporting frame in the form of a cylinder.

The end module has the shape of a cone, while the supporting frame contains vertical, horizontal and annular profiles interconnected to form a supporting frame in the form of a cone.

The end module has the shape of a rectangular parallelepiped, while the supporting frame contains vertical and horizontal profiles interconnected to form a supporting frame in the form of a rectangular parallelepiped.

The shape of the end modules is the same. The shape of the end modules is different.

The intermediate module is in the form of a hollow cylinder, while the carrier frame contains vertical, horizontal and annular profiles interconnected to form a carrier frame for the intermediate module in the form of a hollow cylinder.

The intermediate module has the shape of a rectangular parallelepiped, while the supporting frame contains vertical and horizontal profiles interconnected to form a supporting frame for the intermediate module in the form of a rectangular parallelepiped.

The intermediate module is formed from several intermediate modules connected to each other by means of a flange connection.

The supporting frame of the module is made of metal. The supporting frame of the module is made of composite material. The supporting frame of the module is made of wood.

Bearing frames of adjacent modules are interconnected by means of fasteners.

Additionally, shelves are installed, fixed on the supporting frame of the module.

The casing of the module is made of plastic by rotational molding.

The housing additionally contains openings for supply and exhaust ventilation.

Adjacent modules are connected to each other by soldering the skin on the inside. Adjacent modules are interconnected by soldering the skin from the outside.

Mounting protrusions are made from the outer side of the skin in the area of the openings.

Mounting tabs contain transverse stiffeners connected to the outer surface of the skin.

Adjacent modules are additionally connected to each other by means of mounting protrusions and connecting elements to form a flange connection.

The entrance mouth is equipped with a ladder.

In the context of the present description, the terms "hemisphere", "cylinder", "cone", "rectangular parallelepiped", means shapes essentially close to the indicated geometric figures. As it will be clear to a specialist, taking into account various technologies and materials of manufacture, the implementation of fillets, chamfers, the presence of seams, the presence of an inlet neck and other structural elements, etc. the shape of the product may differ from the shape of the corresponding geometric figure.

The technical result achieved as a result of solving the problem is to expand the arsenal of funds for the construction of cellars. An additional technical result is to increase the stability of the cellar to the external pressure of the soil.

Brief description of the drawings

Figure 1 - the design of the inventive cellar according to a non-limiting embodiment (general side view).

Figure 2 - design of the proposed cellar according to a non-limiting embodiment (general view in section)

Description

Figure 1 and Figure 2 shows the design of a non-limiting embodiment of the inventive cellar 100.

The cellar 100 includes a hollow body 102 with an inlet 103 for user access inside the body 102. The body 102 consists of two end modules 1021 and 1022 and an intermediate module 1023 located between the end modules 1021 and 1022. Further, the end module 1021 and the intermediate module 1023 as well as intermediate module 1023 and end module 1022 may be referred to as adjacent modules. In general, the end modules 1021, 1022 and the intermediate module 1023 may be referred to as modules (1021, 1022, 1023).

Each module (1021, 1022, 1023) contains a supporting frame 202 (figure 2), formed from interconnected profiles 204, oriented in three planes to form a three-dimensional frame.

An embodiment (FIGS. 1-2) is possible, according to which the end module 1021,1022 is hemispherical in shape, while the supporting frame 202 contains vertical, horizontal, radial and annular profiles 204 interconnected to form a hemispherical supporting frame.

An embodiment is possible, in which the end module is in the form of a cylinder, while the supporting frame contains vertical, horizontal and annular profiles interconnected to form a supporting frame in the form of a cylinder. (not shown in figures)

An embodiment is possible, in which the end module is in the form of a cone, while the supporting frame contains vertical, horizontal and annular profiles interconnected to form a supporting frame in the form of a cone. (not shown in figures)

An embodiment is possible, in which the end module has the shape of a rectangular parallelepiped, while the supporting frame contains vertical and horizontal profiles interconnected to form a supporting frame in the form of a rectangular parallelepiped. (not shown in figures)

An implementation option is possible, according to which the shape of the end modules 1021 and 1022 is the same. For example, as shown in FIG. 1-2 both end modules 1021 and 1022 are hemisphere shaped. Other combinations are possible, for example, both end modules can be in the form of cones or cylinders or rectangular parallelepipeds.

Embodiments are also possible, according to which the shapes of the end modules of the cellar may differ. For example, one end module may be a cylinder and the other a hemisphere, or for example, one may be a cylinder and the other a cone, or for example, one may be a hemisphere and the other a cone, etc.

It is also possible that one or both of the end modules may have a complex shape formed by a combination of different geometric shapes. (not shown).

An embodiment is possible in which the intermediate module 1023 is in the form of a hollow cylinder (shown in Figs. 1-2), while the supporting frame 202 contains vertical, horizontal and annular profiles interconnected to form a supporting frame 202 for the intermediate module in the form of a hollow cylinder.

An embodiment is possible, according to which the intermediate module has the shape of a rectangular parallelepiped, while the supporting frame contains vertical and horizontal profiles interconnected to form a supporting frame for the intermediate module in the form of a rectangular parallelepiped.

A variant of implementation is possible, according to which the intermediate module is formed from several intermediate modules connected to each other by means of a flange connection. In this way, cellars 100 with the required volume can be created during production by using a single or composite (consisting of several parts) intermediate module 1023 and two end modules 1021 and 1022.

The support frame 202 of each individual module 1021,1022, 1023 may be made of metal, composite material, wood, or a combination thereof. The supporting frame 202 may be formed by interconnecting profiles 204 by welding, soldering and/or fasteners such as bolting, rivets, nails, screws, etc.

Support frames 202 of adjacent modules 1021, 1023 and 1023, 1022 can be connected to each other, for example, by means of fasteners or by welding. According to an alternative embodiment, the support frames 202 of the individual modules may not be connected to each other when the cellar 100 is assembled at the factory.

An embodiment is possible according to which shelves 206 (FIG. 2) and/or other storage means such as cabinets, drawers, etc. can be installed on the supporting frame 202. (not shown). Shelves 206 may be made of, for example, wood, metal, plastic, and may be fixed to the base frame 202 of one or more modules 1021, 1022. In this case, as will be clear to a person skilled in the art, the installation of shelves can further increase the rigidity of the base frame 202 and increase stability of the cellar 100 to the external pressure of the soil.

The size, shape, thickness, type and number of profiles 204 in the supporting frame 202 are not specifically limited in any way and can be selected based on the required strength indicators, material consumption and based on the overall dimensions of the cellar 100.

A plastic skin 208 is installed over the carrier frame 202 to form a module container. The module skin 208 can be made of plastic by rotational molding or injection molding methods, it is also possible that the skin 208 is made by soldering individual elements. Each end module (1021, 1022) contains an opening, and each intermediate module 1023 contains two openings, enabling the containers of the end modules 1021, 1022 and the intermediate module 1023 to be combined into a single container, adjacent modules 1021, 1023 and 1023, 1022 are interconnected. The skin 208 has a neck 103. In addition to the neck 103, the skin may contain additional technological holes and/or openings. In particular, an implementation option is possible, according to which the housing 102 additionally contains openings for supply and exhaust ventilation.

Connecting adjacent modules (1021, 1022, 1023) may be accomplished in one or more different ways. Adjacent modules (1021, 1023 and 1023, 1022) can be interconnected by soldering the skin on the inside. Adjacent modules (1021, 1023 and 1023, 1022) can be interconnected by soldering the skin from the outside. An embodiment is possible according to which mounting projections 210 are made on the outer side of the skin 208 in the region of the openings. In this case, the connecting elements 212 can be, for example, bolts with nuts. As will be clear to the expert, it is possible to use other connecting elements, in particular, rivets, clips, etc.

Mounting tabs 210, according to a non-limiting embodiment, may further comprise transverse stiffeners associated with the outer surface of the skin 208. The transverse stiffeners may further enhance the rigidity of the supporting frame 202 and increase the resistance of the cellar 100 to external ground pressure.

Cellar 100 can be additionally equipped with additional equipment mounted at the factory. In particular, the inlet 103 may be provided with a ladder. The mouth 103 may be located at an angle to the body 102 (shown in Fig.1) with the formation of a gentle entrance to the cellar, or the neck 103 may be located perpendicular to the body 102 and made in the form of a hatch, with the formation of a vertical entrance to the cellar. An embodiment is also possible, according to which at least one additional neck 103 can be made in the housing 102.

The inventive cellar 100 can be made, for example, as follows. For example, a standard rotational molding machine can be used to produce casing 208 from a polymeric material (plastic) by rotational molding. In this way, separate modules 1021, 1022 and 1023 can be produced separately. Then, from the profiles 204, a supporting frame 202 is assembled for each of the modules 1021, 1022 1023 by welding and / or assembly, depending on the selected material of the profiles and the selected design. If necessary, additional equipment is placed, for example, shelves on the supporting frame 202. Then the supporting frame 202 is placed in the casing of the module 208, after which the modules are connected in the area of the openings to form a single cellar capacity. Adjacent modules (1021, 1023 and 1023, 1022) are connected by soldering and/or through fasteners and mounting protrusions made on the skin 208. An embodiment is also possible, according to which, after connecting the adjacent modules (1021, 1023 and 1023, 1022), also the interconnection of supporting frames 202 of adjacent modules (1021, 1023 and 1023, 1022).

After assembling the cellar 100 at the factory, it is delivered to the installation site and installed in a pre-prepared pit equipped with a foundation, the body 102 of the cellar 100 is buried, after which the cellar is ready for operation, and the presence of the supporting frame 202 ensures the stability of the cellar 100 to external soil pressure , in particular, prevents deformation of the housing 102.

The presented illustrative embodiments, examples and description serve only to provide an understanding of the claimed technical solutions and are not limiting. Other possible embodiments will be clear to the skilled person from the description presented. The scope of this utility model is limited only by the appended claims of the utility model.

Claims (23)

1. Cellar, including a hollow body with an inlet for user access inside the body, the body consists of two end modules and an intermediate module located between the end modules, each module contains a supporting frame formed from interconnected profiles oriented in three planes, on top the supporting frame is fitted with a plastic sheathing to form a module capacity; each end module contains an opening, and the intermediate module contains two openings, providing the possibility of combining the containers of the end modules and the intermediate module into a single container, adjacent modules are interconnected. 2. The cellar according to claim 1, in which the end module has the shape of a hemisphere, while the supporting frame contains vertical, horizontal, radial and annular profiles interconnected to form a supporting frame for the end module in the form of a hemisphere. 3. Cellar according to claim 1, in which, the end module is in the form of a cylinder, while the supporting frame contains vertical, horizontal and annular profiles interconnected to form a supporting frame for the end module in the form of a cylinder. 4. Cellar according to claim 1, in which, the end module has the shape of a cone, while the supporting frame contains vertical, horizontal and annular profiles interconnected to form a supporting frame for the end module in the form of a cone. 5. The cellar according to claim 1, in which the end module has the shape of a rectangular parallelepiped, while the supporting frame contains vertical and horizontal profiles interconnected to form a supporting frame for the end module in the form of a rectangular parallelepiped. 6. Cellar according to claims 1-5, in which the shape of the end modules is the same. 7. Cellar according to claims 1 to 4, in which the shape of the end modules is different. 8. The cellar according to claim 1, in which the intermediate module is in the form of a hollow cylinder, while the supporting frame contains vertical, horizontal and annular profiles interconnected to form a supporting frame for the intermediate module in the form of a hollow cylinder. 9. The cellar according to claim 1, in which the intermediate module has the shape of a rectangular parallelepiped, while the supporting frame contains vertical and horizontal profiles interconnected to form a supporting frame for the intermediate module in the form of a rectangular parallelepiped. 10. Cellar according to claim 1, in which the intermediate module is formed from several intermediate modules connected to each other by means of a flange connection. 11. Cellar according to claim 1, in which the supporting frame of the module is made of metal. 12. Cellar according to claim 1, in which the supporting frame of the module is made of a composite material. 13. Cellar according to claim 1, in which the supporting frame of the module is made of wood. 14. Cellar according to claim 1, in which the supporting frames of adjacent modules are interconnected by means of fasteners. 15. The cellar according to claim 1, in which shelves are additionally installed, fixed on the supporting frame of the module. 16. Cellar according to claim 1, in which the casing of the module is made of plastic by rotational molding. 17. The cellar according to claim 1, in which the housing additionally contains openings for supply and exhaust ventilation. 18. The cellar according to claim 1, in which adjacent modules are interconnected by soldering the lining from the inside. 19. The cellar according to claim 1, in which adjacent modules are interconnected by soldering the skin from the outside. 20. The cellar according to claim 1, in which mounting protrusions are made on the outer side of the skin in the area of the openings. 21. The cellar according to claim 20, in which the mounting protrusions contain transverse stiffeners associated with the outer surface of the skin. 22. Cellar according to claim 20, in which adjacent modules are additionally connected to each other by means of mounting protrusions and connecting elements to form a flange connection. 23. Cellar according to claim 1, in which the inlet is equipped with a ladder.

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