RU108025U1 - THERMOCONTAINER - Google Patents

Abstract

 1. A container containing a detachable composite case, a lid and a bottom made of flexible (foamed) heat-insulating material and covered from the outside with a single fabric cover, as well as incompletely ring zippers located on the side surface of the cover, with a cavity formed by the body constituent parts for a container with a product and at least one cavity for heat and cold elements, separated by at least one mesh partition sewn around the perimeter in the case, and one zipper is located on the nke cavity bottom with a product container which is a mesh partition, and the other at the edge of this cavity, with the tilt of the case with a cavity for heat-ice packs. ! 2. The thermal container according to claim 1, characterized in that the housing is made with a cavity for heat and cold elements from the bottom. ! 3. The thermal container according to claim 1, characterized in that the housing is made with a cavity for heat and cold elements from the side of the lid. ! 4. The thermal container according to claim 1, characterized in that the housing is made with two cavities for heat and cold elements - from the bottom and from the side of the lid. ! 5. Thermal container according to any one of claims 1 to 4, characterized in that the housing is vertically oriented, of constant cross section in height. ! 6. Thermal container according to any one of claims 1 to 4, characterized in that the housing is cylindrical. ! 7. Thermal container according to any one of claims 1 to 4, characterized in that a carrying handle is located above the lid. ! 8. Thermal container according to any one of claims 1 to 4, characterized in that in the housing there are cavities for heat and cold elements from the group: salt heat element, gel cold element. ! 9. Thermal container according to any

Description

The utility model relates to constructions of containers with thermal insulation intended for storage and transportation of perishable products.

Known thermostat operating on mains power or battery, and consisting of a thermally insulated body, a working chamber, a cooling unit, a power supply, a fan, a temperature setpoint, a temperature sensor (RU No. 2076350).

Known portable thermostat for transportation and storage of biological substances, containing a thermally insulated body, a working chamber, thermoelectric module, radiator, fan (RU No. 2054608).

A common disadvantage of the above devices is their complexity, the need to disconnect from the source of electricity during transportation, the inability to work independently from the source of electricity.

Known thermal container designed for storage and transportation of biological objects while maintaining their properties. It consists of a case with thermal insulation, a cover with a sealing gasket, an inner chamber with a removable cartridge for a heat transfer medium containing from 1 to 9 cells for thermostatic material, a thermoelectric installation of two thermocouples, a power supply unit, a thermostatic control unit and a fan, pipelines, an electronic unit (RU No. 2221971).

This device allows you to store and transport biological objects while maintaining their properties, however, the complexity of the design, the high price of the product and the need for a constant current source from the network or a powerful battery limits the possibility of using this device.

A known container for biological objects, containing a thermally insulated body with a lid and an inner chamber, while in the lower part of the inner chamber of the housing is a pencil case designed to accommodate a cooler made in the form of a sealed container made, for example, of hardened rubber and filled with a cooling agent, above a tripod is placed with a pencil case with holes for boxes of various sizes, and on the inner surface of the lid there is a heat-insulating material with a thickness equal to the height of the free space above the tripod (see RU No. 42634).

The disadvantages of the known device adopted for the prototype are the irrational use of the volume of the working chamber due to the presence of a tripod, as well as the short service life during which the container can correspond to provide cooling.

Known thermal container bag, made in the form of a chest, containing the outer and inner shells made of textile material, between which is placed an insulating fence with an internal cavity, a working chamber, a lid mounted above the cavity of the working chamber, the latter is made in the form of a hollow rectangular parallelepiped open from above or a hollow cylinder, open at the top, and the thermal container bag also contains a removable container made of rigid material, which is open on top and is installed in the inner Yu cavity thermally insulating enclosure. The inner shell is made in the form of a removable cover that surrounds the surface of the insulating fence, and the removable container is made of sheet material approved for use in medical technology, for example, a polymeric material or stainless steel. At least one heat-insulating damper installed between the lid and the cavity of the working chamber is included in the composition of the thermal container bag. The damper is made of two layers of textile material connected between each other at the edges, between which at least one layer of heat-insulating material is placed, and the damper is mounted on the inner shell with the possibility of rotation of at least 180 ° relative to the horizontal axis (RU No. 2330220, prototype).

The disadvantages of the known thermocontainer are the complexity of the design, which is due to low reliability, and the limited functionality of the product placement due to the irrational placement of heat and cold elements.

The objective of the utility model is to create an effective thermal container and expand the arsenal of thermal containers.

The technical result that provides a solution to the problem is to simplify the design by rational placement of heat and cold elements and the design of the composite housing, while increasing reliability and expanding functionality.

The essence of the utility model is that the temperature container contains a detachable composite case, a lid and a bottom made of elastic (foamed) heat-insulating material and covered from the outside with a single fabric cover, as well as incomplete ring zippers located on the side surface of the cover, while the components of the body form a cavity for the container with the product, and at least one cavity for heat and cold elements, separated by at least one mesh partition sewn around the perimeter in the case, a zipper disposed on the wall of the cavity for the product, which container bottom is the mesh partition, and the other - the edge of the cavity with the ability to tilt the cover part with a cavity for thermal ice packs.

In special cases of implementation, the body is made with a cavity for heat and cold elements from the bottom side or the body is made with a cavity for heat and cold elements from the side of the lid, or the body is made with two cavities for heat and cold elements from the bottom and from the side of the cover.

Preferably, the casing is made vertically oriented, of constant cross section in height, the casing is made cylindrical, a carrying handle is located above the lid, cavities for heat and cold elements from the group are made in the body: salt heat element, gel cold element, the body is made in the form of a hollow cylinder, detachable in annular cross sections, the cavity for the container with the product is made detachable from two parts of the body.

In the drawing of Fig. 1, a plan view of the thermocontainer is shown, in Fig. 2 is a structural diagram of a thermocontainer with one cavity for heat and cold elements, Fig. 3 is a structural diagram of a thermocontainer with two cavities for heat and cold elements, in Fig. 4 - volumetric image of the thermal container in axonometric projection, FIG. 5 is a three-dimensional image of the thermal container in axonometric projection with a section of the housing, FIG. 6 is a structural diagram of a housing connector, FIG. 7 is a salt heat element and a gel cold element.

The container contains a detachable composite case of parts 1, 2, 3, 4, a cover 5 and a bottom 6 made of solid heat-insulating material and covered from the outside with a single cover 7 of fabric, as well as incomplete ring zippers 8 located on the side surface of the cover 7 Two detachable parts 1, 2 of the body formed a detachable cavity for the container (container) 9 with the product, components 3, 4 - cavities for heat and cold elements 10, 11, separated by one (figure 2) or two (figure 3-5 ) sewn around the perimeter in the cover 7 mesh partition 12. One clasp-m Zipper 8 is located on the wall of the cavity for the container 9 with the product bottom of which is a mesh partition 12, and the other at the edge of this cavity with the possibility of folding part of the cover 7 with the cavity for heat and cold elements 10, 11.

The housing in figure 2 is made with a cavity for heat and cold elements from the bottom 6, formed by part 3 of the housing.

The housing in FIGS. 3-5 is made with two cavities for heat and cold elements - from the bottom 6 and from the side of the cover 5, formed by parts 3, 4 of the housing.

The housing is cylindrical, vertically oriented, of constant cross-sectional height, detachable in annular cross sections along the mating surfaces of parts 1-4 of the housing.

Above the lid 5 is a handle 13 for carrying.

In the housing, cavities for heat and cold elements from the group are made: salt heat element 10, gel cold element 11.

Thermal container is operated as follows.

In the assembled position, parts 1-4 of the body are assembled in a single cylinder, divided into cavities by mesh partitions 12. In cavities adjacent to the cover 5 and to the bottom, 6 heat elements 10 or cold elements 11 are stacked. In the cavity formed in the middle part of the body the container is loaded with thermostatic product. Zippers 8 are fastened and the thermal container is ready for transportation. When carrying the thermal container use the handle 13.

The conjugation of parts 1-4 of the housing (consisting of thermal insulation material) is carried out practically without a gap, which eliminates convective and conductive heat fluxes from the housing, and significantly increases the duration of passive maintenance of a given temperature storage mode of heat-sensitive products during their transportation.

At the place of unloading, the zipper 8 is unzipped at the interface between the body parts 1, 2 and the container 9 is removed from the thermal container. If necessary, the corresponding zippers 12 are unfastened and the parts 3, 4 of the case are tilted, and the mesh partitions 12 remain on the parts 1, 2 of the case, which allows the replacement of heat elements 10 or cold elements 11.

For reuse, the thermal container is assembled in its original position in the reverse order.

After each act of using the thermal container, there is no need to disinfect its elements made of textile materials (case 7). First of all, parts 1-4 of the body must undergo mandatory disinfection.

Thus, the container consists of the simplest elements and elementary body parts, and the operation of the thermal container is reduced to the simple actions of unfastening the zipper and turning (folding) and pairing the parts of the case.

As a result, an efficient thermal container was created and the arsenal of thermal containers was expanded.

At the same time, the simplification of the design is ensured due to the rational placement of heat and cold elements and the design of the composite case, while increasing reliability and expanding functionality.

Claims (10)

1. A container containing a detachable composite case, a lid and a bottom made of flexible (foamed) heat-insulating material and covered from the outside with a single fabric cover, as well as incompletely ring zippers located on the side surface of the cover, with a cavity formed by the body constituent parts for a container with a product and at least one cavity for heat and cold elements, separated by at least one mesh partition sewn around the perimeter in the case, and one zipper is located on the nke cavity bottom with a product container which is a mesh partition, and the other at the edge of this cavity, with the tilt of the case with a cavity for heat-ice packs. 2. The thermal container according to claim 1, characterized in that the housing is made with a cavity for heat and cold elements from the bottom. 3. The thermal container according to claim 1, characterized in that the housing is made with a cavity for heat and cold elements from the side of the lid. 4. The thermal container according to claim 1, characterized in that the housing is made with two cavities for heat and cold elements - from the bottom and from the side of the lid. 5. Thermal container according to any one of claims 1 to 4, characterized in that the housing is vertically oriented, of constant cross section in height. 6. Thermal container according to any one of claims 1 to 4, characterized in that the housing is cylindrical. 7. Thermal container according to any one of claims 1 to 4, characterized in that a carrying handle is located above the lid. 8. Thermal container according to any one of claims 1 to 4, characterized in that in the housing there are cavities for heat and cold elements from the group: salt heat element, gel cold element. 9. Thermal container according to any one of claims 1 to 4, characterized in that the casing is made in the form of a hollow cylinder, detachable in annular cross sections. 10. Thermal container according to any one of claims 1 to 4, characterized in that the cavity for the product container is made detachable from two parts of the housing.