RU219023U1 - Prefabricated Vacuum Insulated Thermal Container - Google Patents

Abstract

The utility model relates to logistics equipment, namely, portable thermal containers for transporting sensitive objects that require maintaining certain temperature conditions throughout the entire delivery period, and can be used in the transportation and storage of medicines, transplants, biomaterials, vaccines, medical supplies, products food and other thermolabile objects in conditions of high as well as low ambient temperatures. Vacuum insulated thermal container with a prefabricated structure includes a body and a lid made of heat-insulating and protective layers. The supporting body is made of polypropylene, in the form of a parallelepiped or a truncated pyramid, and contains a hinged cover attached to the body with hinges. The thermal container is made according to the container-in-container principle and includes a supporting body with an isothermal body placed in it and its lid, presented in the form of a multilayer structure. The body consists of two layers of expanded polystyrene and vacuum thermal insulation panels. The lid consists of a layer of polystyrene foam, a vacuum heat-insulating panel and a protective membrane made of polypropylene, the inner layer of polystyrene foam for storing thermal accumulators is provided with a shelf, while the isothermal body is equipped with a sensor that monitors the temperature. The utility model, thanks to the prefabricated structure, makes it possible to reduce the production time of the product and increase the maintainability of the thermal container due to the possibility of quick replacement of a failed part. 2 ill.

Description

The utility model relates to logistics equipment, namely, portable thermal containers for transporting sensitive objects that require maintaining certain temperature conditions throughout the entire delivery period, and can be used in the transportation and storage of medicines, transplants, biomaterials, vaccines, medical supplies, products food and other thermolabile objects in conditions of high as well as low ambient temperatures.

Known utility model relating to devices for storing food, namely thermal containers for storing food at negative air temperatures. Essence of the utility model: a thermal container for food storage contains an outer case with a sealed lid, an inner case installed inside the outer case with a gap relative to all its surfaces and forming an air duct, a main instrument compartment, a main temperature control sensor and an electric heater located in the main instrument compartment, a fan , additional temperature sensors, and a partition with a valve located in the cavity between the walls of the outer and inner cases, forming an additional instrument compartment. The inner body is made in the form of several sealed sections, each of which has a perforated partition in the inner cavity, an inlet valve installed at the bottom of the section, and an outlet valve installed in the section cover, with the main temperature control sensor installed in the main instrument compartment, and additional sensors temperature controls are installed in the cavity of each section of the inner housing and connected to the main temperature control sensor. In this case, the fan is installed in an additional compartment, and the cavity of the latter is connected by an air duct to the cavity of each section of the inner housing through its inlet valve (RU 52 662, IPC A01F 25/14, publ. 27.04.2006).

The disadvantages of the known device is the complexity of the design, during the operation of which the failure of one of the sensors of the electrical circuit guarantees damage to the loaded thermolabile objects, as well as unsuitability for operation in the absence of power supply.

Known thermal container for storage and transportation of biological products, containing a body with thermal insulation, a lid with a seal and cold accumulators, an inner container with thermal insulation and a lid with a seal. In the cavities between the walls of the housing and the inner chamber, cold accumulators are located with an air gap. The inner chamber is made with the possibility of alternate air exchange with the environment or the cavity between the walls of the housing and the inner chamber through air ducts with built-in valves that are connected to a temperature sensor, a bellows or a bimetallic spring placed in the inner chamber (RU 2495340, IPC F25D 11/00, F25D 3/14, published 10.10.2013).

The disadvantages of the known device is the irrational use of the volume of the working chamber, as well as the low service life during which the container can meet the sanitary and hygienic requirements for devices intended for temporary storage during transportation of medical thermolabile materials.

Known container with vacuum insulation, which contains a sealed outer container and installed in it with a gap forming a vacuum cavity for thermal insulation, a sealed inner container. Each of the containers has a rear, removable front, top, bottom and side walls, each of which is made of a group of concave sheets attached to the transverse beams and sections of the longitudinal corner beams enclosed between them. The sheets are fixed in such a way that the distance between the peripheral sections of the sheets of the respective outer and inner wall frame sections exceeds the distance between their central sections. Each sheet of the outer and inner wall frame sections is made with the possibility of transferring to the frame beams the tensile loads acting on them from the environment and the pressure of the product in the container, which generally increases the reliability of the container operation (SU 1556534, 5B65D 88/00, IPC 5B65D 81/ 38, published 04/07/1990).

However, in this case, the use of vacuum as thermal insulation will not give the desired effect, since there are cold bridges as longitudinal and transverse beams.

A device is known that contains two concentrically mounted cups made of vacuum-tight material, between which vacuum-powder thermal insulation is placed. The gap between the glasses is closed from above by a spacer ring. The cover has a fitting for connecting a vacuum pump. A non-return valve is installed in the fitting. An additional check valve is located in the distance ring. It communicates with thermal insulation, with a through fitting and with a cavity for placing biological objects in the inner glass. A perforated cup plugged on one side can be fixed on the spacer ring. An additional check valve can be placed in this glass, and a filter is placed between them (RU 2132522, IPC F25D 3/00, publ. 06/27/1999).

The disadvantage of this design is that during operation, due to repeated pumping and pressure relief, moisture will accumulate in the vacuum insulation cavity. This is due to the fact that vacuum-powder insulation fillers are highly hygroscopic.

Known thermocontainer, which contains a body and a lid. To increase the reliability of the thermal container, to ensure the possibility of keeping food hot for a long time and cooking it, the thermal container is equipped with a removable element made of aluminum sheet shielded with metal foil and located at the bottom of the thermal container, the body and cover are rectangular, while the heat-reflecting layers are located outside and inside housings and covers, and a heat-insulating layer between them. The cover of the thermocontainer is supplied with the handle. The body and cover of the thermal container are covered with a protective material from the outside, the heat-insulating layer of the body is made of expanded polystyrene 40-60 mm thick, and the covers are 40-120 mm thick, the thickness of the removable element is 0.2-0.4 mm, the heat-reflecting layers are made of metal foil, for example aluminum. The thermal container can be equipped with latches (RU 152221, IPC A47J 39/02, A47J 41/02, B65D 81/38, published on May 10, 2015).

The disadvantage of the known model are the overall dimensions and wall thickness. This is due to the fact that in order to provide sufficient thermal insulation in this utility model, a layer of expanded polystyrene up to 120 mm was laid.

The closest in technical essence to the proposed technical solution is a thermal container, including a body and a cover made of heat-insulating and heat-reflecting layers, a thermal container cover with a handle, a thermal container equipped with latches, characterized in that the body made of polypropylene in the form of a parallelepiped or a truncated pyramid is impact-resistant and contains a hinged lid attached to the body with hinges, the body is a multilayer structure consisting of a carrier shell of the body made of polypropylene, heat-insulating layers with a closed loop in the form of polyurethane foam and vacuum heat-insulating panels, a heat-reflecting membrane on the inside, moreover, as the main heat-insulating material, vacuum heat-insulating panels are used, which are made of evacuated nanostructured silicon dioxide powder packed in a heat-resistant polymer film (RU 197942, IPC B65D 81/38, F25D 3/14, publ. 06/08/2020).

The disadvantage of this model is monolithic polyurethane foam, since this material in the production process described in the patent implies waiting for the layers to set, which in itself increases the production time of the product.

The technical result of the claimed solution is to improve and implement a prefabricated structure, which will subsequently reduce the production time of the product, as well as improve the maintainability of the thermal container due to the possibility of quick replacement of a failed part.

The technical result is achieved due to the fact that the thermal container with vacuum insulation with a prefabricated structure includes a body, a cover, and a working chamber, while the body and cover are a multilayer structure consisting of a carrier shell of the body made of polypropylene and a heat-insulating layer with a closed loop in in the form of vacuum panels made of nanostructured silicon dioxide powder and packed in a polymer film. The supporting body is made of polypropylene in the form of a parallelepiped or a truncated pyramid and contains a hinged lid attached to the body with hinges. The thermal container is made according to the principle of a container in a container and includes a supporting body with an isothermal body and its lid placed in it, presented in the form of a multilayer structure. The body consists of two layers of expanded polystyrene and vacuum thermal insulation panels. The cover is composed of a layer of polystyrene foam, a vacuum thermal insulation panel and a protective membrane of polypropylene, the inner layer of polystyrene foam for storing thermal accumulators is provided with a shelf. The isothermal body is made with the ability to disassemble it during operation and replace parts that have failed, while it is equipped with a temperature monitoring sensor.

Figure 1 shows the design of the thermal container in the section in the longitudinal direction;

figure 2 is a section in the transverse direction.

The thermal container (Fig. 1, 2) includes a carrier 1 and an isothermal body 2, as well as a working chamber 3. The carrier body 1 is made of polypropylene in the form of a parallelepiped or a truncated pyramid, with a hinged lid 4. The isothermal case 2 and its cover 5 are in a multilayer structure. The cover 5 of the insulated housing 2 consists of a layer of expanded polystyrene 6, a vacuum thermal insulation panel 7, and a protective membrane made of polypropylene 8. evacuated nanostructured silica powder packed in a multilayer polymer film. The inner layer of expanded polystyrene 10 for storing thermal accumulators is provided with a shelf 11. Isothermal housing 2 is made in such a way that during the operation of the product it can be disassembled and parts that have failed can be replaced. The lid 5 of the insulated housing 2 is closed due to a snug fit to the housing 2. The thermal container is equipped with transport handles (not shown in the drawing) located on the carrier housing 1. The hinged lid 4 is fixed to the carrier housing 1 with the help of hinges 12. The thermal container is equipped with thermal accumulators 13 and a sensor ( not shown in the drawing), monitoring the temperature.

The following materials can be used to manufacture the thermal container: polypropylene that meets the requirements of GOST 26996-86 "Polypropylene and propylene copolymers"; Expanded polystyrene that meets the requirements of GOST 15588-2014 “Polystyrene foam heat-insulating plates. Specifications"; vacuum insulated panels meeting the requirements of ASTM C1484 - 10 (2018) "Standard Specification for Vacuum Insulated Panels".

The thermal container is assembled in the following order. The first layer of expanded polystyrene 9 of the isothermal body 2 is placed in the bearing body 1. Then vacuum heat-insulating panels 7 are installed in the design position, and then the second layer of expanded polystyrene 10 is immersed. The cover 5 of the isothermal body 2 is assembled in the following order. A vacuum heat-insulating panel 7 is placed in the niche of the expanded polystyrene layer 6 of the cover of the insulated housing 2 and a protective membrane of polypropylene 8 is glued on top with glue. 7. Thermal accumulators 13 are placed in the working chamber 3, the cover 5 of the isothermal housing 2 is tightly closed.

During operation, the thermal container is used as follows. The regime object is loaded into the working chamber 3. Together with it, if necessary, thermal accumulators 13 are placed, prepared for a certain temperature regime. The total volume of thermal accumulators is calculated from the required temperature regime and temperature control time. The cover 5 of the isothermal body 2 is tightly closed, and then the hinged cover 4 of the carrier body 1 is closed. After the operating time of the thermal accumulators 13 or the temperature inside the working chamber 3 approaches the maximum allowed, the thermal accumulators 13 can be replaced by placing the container in the temperature zone to prevent the temperature inside working chamber 3 outside the set temperature. The thermal container can be used with a temperature-monitoring sensor (logger) (not shown in the drawing). The thermal container is aimed at improving the safety of transported objects and is a reusable object.

Compared to the known solution, the proposed one uses a prefabricated structure, which allows to reduce the production time of the product and increase the maintainability of the thermal container due to the possibility of quick replacement of a failed part.

Claims (1)

Thermocontainer with vacuum insulation with a prefabricated structure, including a body, a cover and a working chamber, while the body and cover are a multilayer structure consisting of a carrier shell of the body made of polypropylene and a heat-insulating layer with a closed loop in the form of vacuum panels made of nanostructured powder silicon dioxide and packed in a polymer film, the body is made in the form of a parallelepiped or a truncated pyramid and contains a hinged lid attached to the body with hinges, characterized in that the thermal container is made according to the principle of a container in a container and includes a carrier body with an isothermal body placed in it and its cover, presented in the form of a multilayer structure, where the body consists of two layers of expanded polystyrene and vacuum heat-insulating panels, the cover consists of a layer of expanded polystyrene, a vacuum heat-insulating panel and a protective membrane made of polypropylene, the inner layer of expanded polystyrene for storing thermal accumulators is equipped with a shelf, the isothermal body is made with the possibility disassemble it during operation and replace parts that have failed, while it is equipped with a sensor that monitors the temperature.

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