RU205617U1 - Collapsible refrigerated display case with convection cooling - Google Patents

Abstract

The utility model relates to commercial equipment, namely to display cabinets with refrigeration. The solution task of the claimed utility model is to reduce the labor costs of production and expand the functionality of use. The technical result is achieved through the implementation of a collapsible refrigerated display cabinet with convection cooling, containing a refrigeration an installation including a compressor, a condenser, an evaporator, as well as a fan (s) and a refrigeration chamber, which includes side walls, back and front walls, top and bottom panels made of thermal insulation materials, and shelves. The refrigeration unit is mounted on a single flat mounting panel, which is located on top of the refrigerating chamber on its upper panel, the evaporator and fans are enclosed in a heat-insulating casing, and the part of the mounting panel enclosed in this casing, as well as the upper panel of the refrigerating chamber have continuous openings, the refrigerating chamber contains racks for fastening the walls and panels, while the dimensions of the lower and upper panels, as well as the side walls, are respectively unified, the rear wall is made with horizontal rows of unified panels, the front wall is made with a frame with doors, under which the thermal insulation protection is located at the bottom of the cabinet, doors include transparent material. The bottom and top panels, back wall, refrigeration unit and frame with doors are scalable to the length of the display cabinet. 6 c.p. f-crystals, 4 fig.

Description

The utility model relates to commercial equipment, namely to refrigerated display cabinets.

Currently, display cabinets with refrigerated chambers are widespread in shops, bars, restaurants. In most cases, the designs of such cabinets differ little and represent a chamber or a set of chambers, the air space of which is cooled using refrigeration units, including a compressor, a condenser and an evaporator. A typical example of such a design is, for example, the display cabinets of the Terem-Kholod company (http://terem-holod.ru/produkcija/holodilnoe-oborudovanie/steklyannie-i-gluhie-fronty/). The disadvantage of such structures is a significant temperature spread over the volume of the refrigerated chamber, which is associated with the need for additional measures to normalize the microclimate due to the asymmetric arrangement of refrigeration units, increased labor costs for the production of components and during installation, reduced maintainability, structural obstacles to convective air exchange due to low air permeability of the structure of the shelves.

Also known is the design of a refrigerator cabinet, comprising an exhibition module in the form of a heat-insulated cabinet with internal shelves, the front side of which is equipped with a transparent door, and in the upper part there is a facing box formed by the front and side walls, with an installation opening from the rear; side, and inside the specified box is a removable cooling module containing a compressor, a condenser and an evaporator enclosed in a heat-insulating casing, and the compressor, condenser and evaporator are mounted directly on a single base plate (panels), and the ceiling panel of the exhibition module and the base plate of the cooling module are provided with mating holes for air circulation, characterized in that the evaporator is mounted on the back of the base plate parallel to the rear panel of the cabinet, and these holes form two channels with an elongated cross-section, parallel to the rear panel of the cabinet, the first of which is located closer to the central part of the ceiling panel and communicates on the one hand, directly with the internal volume of the cabinet and on the other side - with the evaporator inlet, and the second is located closer to the rear of the ceiling panel and communicates on one side with the evaporator outlet, and on the other, with an air duct running along the entire rear panel of the cabinet and is equipped with outlet openings made between each pair of shelves and leading into the inner volume of the cabinet (RF patent for utility model No. 197434, MKI A47F 3/04, F25D 17/06, 2020). The disadvantage of this design is the low manufacturability of the product, i.e. increased labor costs for the production of components and during installation of the cabinet, reduced maintainability, as well as the lack of the possibility of horizontal scaling of the product module.

The closest in terms of the totality of essential features to the claimed utility model is a modular refrigeration display system assembled at the point of sale and containing: a plurality of components for a modular refrigeration unit capable of being assembled at the point of sale into at least one display case providing visual access to the interior of the showcase, and at least one stationary unit, wherein a portion of the showcase provides visual access to the interior of the showcase, wherein the plurality of components are stackable one on top of the other and placed in a generally flat configuration when not assembled, wherein, at least one display case is configured to be attached to the upper surface of at least one stationary unit, which includes a convective-conductive refrigeration unit pre-assembled at a location remote from the place of sale and detachably attached to the mod refrigeration unit, and the display case includes a sensor system that is associated with a conductive refrigeration unit, and the plurality of components for a modular refrigeration unit include one or more of the following: top walls, bottom walls, side walls, back walls, doors, front walls, and shelves. The specified modular refrigeration display system in the minimum version is a single-section display cabinet with a refrigeration unit located at the bottom of the refrigerated chamber (RF patent for invention No. 2 560 271, MKI A47F 3/04, 2012). The disadvantages of such a system are the increased labor costs for the production of components, as well as during the installation of the cabinet, the lack of interchangeability of structural elements, the reduced maintainability of the product, and the inability to horizontally scale the product modules.

The task to be solved of the claimed utility model is to eliminate the shortcomings of the above technical solution and achieve the technical result: increasing the manufacturability of the display cabinet design by unifying the component structural elements (parts) and the constructive possibility of increasing its cooled space.

Such a technical result, in particular, includes a decrease in labor costs in the production of components and in the installation of a structure, as well as an increase in maintainability by reducing the range of components, unifying their sizes and shapes. In addition, the unification of the size and shape of the components makes it possible to increase the refrigerated space through scaling.

Scaling in this description and in the claims of a utility model should be understood as an increase in the dimensions of a device (product) in a certain selected direction due to the connection of structural elements of the device.

Achievement of the specified technical result in the claimed utility model is achieved through the implementation of a collapsible refrigeration display cabinet with convection cooling, containing at least one refrigeration unit, including a compressor, condenser, evaporator, as well as fan (s) and at least at least one refrigerating chamber with the possibility of visual access to its contents, which includes side walls, back and front walls, top and bottom panels made of heat-insulating materials, as well as shelves, differs from the previously known ones in that the refrigeration unit is mounted on a single flat the mounting panel, which is located on top of the refrigerating chamber on its upper panel, the evaporator and fan (s) are enclosed in a heat-insulating casing, and the part of the mounting panel enclosed in this casing, as well as the upper panel of the refrigerating chamber have through holes coordinated in size and location for implementation forced convection exchange along the closed volume of the cabinet, the refrigerating chamber contains racks for fastening the walls and panels, while the dimensions of the bottom and top panels, as well as side walls, respectively, are unified, the lower and upper panels, as well as the refrigeration unit are scalable along the length of the display cabinet, the rear the wall is made in horizontal rows by a set of unified panels and is scalable along the length of the display cabinet, the scaling of unified structural elements is carried out by fixing the edges of these elements on mating racks, the front wall is made with a frame with doors, under which the bottom of the cabinet is equipped with thermal insulation protection, the doors include transparent material, and the frame with doors can be scaled in a row along the length of the display cabinet by linear placement of additional frames with doors.

For an unambiguous and more complete understanding of the description of the claimed utility model, further clarifications and disclosures of the concepts and terms used above, as well as a description of the structure, are given.

The claimed collapsible refrigerated display case with convection cooling is intended for use in shops, bars, restaurants, as well as for storing food in a chilled air atmosphere at temperatures from -5 ° C to + 5 ° C with the possibility of visual inspection and access to them buyers. The display cabinet has a convection cooling mode, which is carried out through the use of a refrigeration unit consisting of a compressor, a condenser, an evaporator, and fans. The equipment in the specified aggregate is mounted on a single panel of a unified size, which is mounting and has a flat shape. The unified size of the mounting panel allows, if necessary, for example, during repairs, to remove and replace the refrigeration unit, as well as to move it in the required direction without distortions and disassembling the entire display cabinet or its part. Thus, the mounting panel with the refrigeration unit mounted on it constitutes a cooling module and is an independent mounting unit. The cooling module is mounted on the top panel of the display cabinet and can be scaled along the arrangement of the top panels in the required amount to achieve the specified cooling mode in the working space of the chamber. In the specified cooling module, the evaporator and fans are located on one side of the mounting plate and are enclosed in a heat-insulating casing. Part of the mounting panel enclosed in this casing has through holes for convection air exchange with the volume of the refrigerating chamber. These holes are aligned with the corresponding holes in the top panel of the cabinet for the same purpose. The evaporator has a predominantly flat configuration and is oriented perpendicularly along the length of the mounting plate. In this case, there may be several fans, preferably two. The axis of the fans is preferably parallel to the plane of the mounting plate and perpendicular to the plane of the evaporator. The edges of the through-holes in the mounting plate have a reinforcing bezel. The cooling module, as a rule, is enclosed with decorative and protective panels. Placing the cooling module on top of the refrigerating chamber allows to increase the working volume of the refrigerating chamber of the display cabinet.

The number of refrigeration modules that the display cabinet contains is determined by maintaining the required temperature regime in the refrigerating chamber, the size of the cabinet and the power of the compressor. For example, a display cabinet 937 mm long contains one cooling module, 1875 mm long - two cooling modules, 2500 mm long - three cooling modules.

The refrigerating chamber of the display cabinet consists of the following structural elements: rear wall, front wall, side walls, top and bottom panels, as well as racks, while the lower panel of the chamber serves as the bottom. All of these elements have a flat rectangular shape and are made of heat-insulating materials. A feature of the camera device is the unification of the size and shape, mirrored structure elements, i.e. there is a corresponding unification of structural elements. Thus, the outer dimensions of the top and bottom panels are the same. The upper panels, designed to accommodate the cooling module, have through holes for convection air exchange through them. These holes in shape and location are coordinated with the holes in the mounting plate of the cooling module, as already mentioned above. The side walls also have the same size and shape. The back wall is made in rows of unified predominantly flat panels, mainly in 2 rows. The refrigerating chamber of the display cabinet consists of the indicated elements, connected by means of racks. Such a connection is carried out by fixing the panels and walls at the mounting points using, for example, threaded rivets. It should be noted that the front wall can be made as a single unit, which is a frame with doors, and the doors include a transparent material, which makes it possible to visually view the products cooled in the cabinet. Thus, the front wall provides the function of physical and visual access to the interior of the display cabinet. The transparent material can be glass, glass unit, plastic glass unit.

The racks of the display cabinet are a vertically extended metal profile, most often it is a perforated profile pipe, for example, a square pipe 40 × 60 × 2.5 mm. The end posts have upper and lower horizontal traverses along the length of the cabinet, directed along the location of the sides. The central (inner) racks have only an upper horizontal traverse, normally directed towards the front wall of the cabinet. Racks and traverses can be made of various construction materials, for example: steel, aluminum alloys, polyurethane, polypropylene, polystyrene, and composite materials. In terms of the form of execution, it is, most often, a hollow profiled profile. Fastening the walls and panels to the uprights is most often performed using threaded rivets. Racks perform an important body-forming function, because are connecting structural elements of the body, namely panels and walls, which are connected by their edges precisely on the racks. This technology of connecting panels allows for scaling of the structure, in which the racks are connecting, mating, structural elements. To increase the strength of the display cabinet, the constituent elements can have appropriate reinforcements, for example, inserts, strips, edging.

The described design assumes a reduction in the nomenclature range and a decrease in labor costs of production in connection with the unification of components. The unification of component structural elements in shape and size leads to a decrease in the labor intensity of installation. The interchangeability of structural elements increases the maintainability of the product and reduces the labor intensity of maintenance.

An important feature of the claimed design is the ability to scale the product linearly in length. Here, scaling should be understood as an increase in the size of the device (product), in this case, linearly along the length of the device due to the use of standardized structural elements.

The refrigerating chamber design described above is a minimal design and is a structural or sub-assembly unit capable of horizontal linear scaling by connecting already assembled sub-assemblies along a line. Moreover, the units can be pre-assembled with or without side walls. Another possibility of organizing an extended product line is the formation of an extended product line immediately during installation by connecting unified elements. The number of assembly units of a fully assembled display cabinet or the scaling factor is determined by production needs or the size of the room. In practice, the maximum number of assembly units reaches 10-12 in a row with a total length of 18 to 23 m.

The claimed utility model is a technical solution, since is a solution to the problem of achieving the claimed technical result by creating a device consisting of structural elements, technologically and structurally interconnected. At the same time, the entire set of essential features of this utility model - the system of structural elements - is united by a single creative concept, namely, by ensuring increased manufacturability of structural elements, installation and repair of the device, as well as expanding its functionality due to the unification of the structural elements of the device - the refrigeration cabinet of the showcase. Parts (elements) of the device are in a constructive unity and a single functional relationship, and their joint use leads to the creation of a new device that allows you to achieve a new technical result.

This technical solution is industrially applicable in the field of refrigeration trade equipment and is applicable as a device for cooling and displaying food. The application and use of the claimed device does not cause any difficulties and can be carried out by ordinary buyers. In the implementation of the technical solution, devices, devices and materials produced by the industry and which are in the public domain are used. Methods for the implementation of the utility model are methods of mechanical processing of structural materials and installation. The means of implementation are mechanical means, machine tools and hand tools for machining. The above set of essential features of the claimed utility model and their disclosure allows us to conclude that the claimed technical result has been achieved, namely, improving the manufacturability of the display cabinet design due to the unification of component structural elements (parts) and the constructive possibility of increasing its cooled space.

In particular, the achievement of this result is expressed in a decrease in labor costs in the production of components, as well as in the installation of a structure due to a reduction in the nomenclature of components, unification of their sizes and shapes, which reduces the labor intensity and time of technological operations of sorting, storage, selection of initial parts by an installer, and also reduces the time the act of mental reprogramming to change the operation, increases ergonomics. The unification of the size and shape of structural components also increases maintainability by reducing the time of access to damaged structural elements and the time for their replacement. In addition, the unification of the size and shape of the components makes it possible to increase the refrigerated space by scaling by connecting the edges of the panels on the mating elements.

Under labor costs and labor intensity, we mean here the time spent, respectively, on the task and individual operations. Reduction of the nomenclature range, unification of components, reduction of labor intensity, interchangeability of structural elements, maintainability - these are characteristics that are a consequence of constructive, i.e. technical changes to the device and its constituent elements in order to improve the manufacturability of the structure. In addition, the reduction of technical operations - the production of structural elements, installation, repair, maintenance are technical operations and hence the reduction in their execution time also refers to the technical characteristics of improving manufacturability.

Thus, we can conclude that the implementation of the full set of essential features of the claimed technical solution allows you to obtain a new technical result, which indicates the constructive and functional unity of the technical solution, which does not contain alternative essential features, as well as alternative sets of essential features.

Distinguishing from the prototype, essential features of the claimed utility model and their characteristics are:

- location of the refrigeration unit on top of the refrigeration chamber,

- location of the evaporator and fans in the heat-insulating casing,

- the presence in the mounting and top panels of through holes coordinated with each other in size and shape for convection air exchange with the volume of the refrigerating chamber,

- the presence of racks for attaching walls and panels,

- unified dimensions of the top and bottom panels, as well as side walls

- the ability to scale along the length of the top panel display cabinet with a refrigeration unit,

- execution of the rear wall of the display cabinet in horizontal rows with a set of unified panels and the ability to scale it along the length of the entire cabinet,

- the implementation of the scaling of unified structural elements by attaching the edges of these elements to mating racks,

- execution of the front wall as a frame with doors, under which thermal insulation protection is located at the bottom of the cabinet, the doors include transparent material, and the frame with doors can be scaled in a row along the length of the display cabinet.

These essential features are distinctive from the prototype, since each of them is not contained in the set of essential features of the prototype, i.e. is not present in the list of features implemented in the prototype and is not their characteristic.

As already shown above, these essential features, which are distinct from the prototype, including their characteristics, ensure the achievement of the claimed technical result when using other essential features of the utility model specified in the description.

Thus, it is shown that the set of essential features of the claimed utility model, which makes it possible to achieve the claimed technical result, differs from the set of essential features of analogues, prototype, as well as other known data sources, i.e. the application of this set of essential features is not known to obtain the claimed technical result. In other words, the claimed utility model is not known from the prior art.

An increase in the efficiency of the claimed technical result is achieved in the following modifications of the method, which characterize particular cases of its implementation:

1. Declared and described above display cabinet, characterized in that the mounting panel has mounting holes for mounting refrigeration equipment.

2. Declared and described above cabinet-showcase, characterized in that the extreme racks of the refrigerating chamber contain two horizontal traverses, one of which is located at the top of the rack, and the other at the bottom.

3. The declared and described above cabinet-display cabinet, characterized in that the central pillars of the refrigerating chamber contain one horizontal traverse, which is located at the upper point of the rack.

4. The declared and described above cabinet-display cabinet, characterized in that the racks are made of a structural perforated profile.

5. The declared and described above cabinet-display cabinet, characterized in that the fastening of the walls and panels to the uprights is performed using threaded rivets.

6. The declared and described above cabinet-display cabinet, characterized in that the back wall is made in two horizontal rows.

The description of the claimed invention is illustrated in FIG. 1-4. FIG. 1 General view of the display cabinet.

FIG. 2 Scheme of linear scaling of the display cabinet in length, Fig. 3 Showcase cabinet, consisting of 3 assembly units, Fig. 4 Refrigeration unit on a mounting plate.

These figures show the following designations:

1. Display cabinet

2. Refrigeration unit

3. Compressor

4. Capacitor

5. Evaporator

6. Fans

7. Mounting plate

8. Refrigerator

9. Top panel

10. Heat insulating casing

11. Holes for convection exchange of the mounting plate

12. Holes for convection exchange of the upper panel of the refrigerating chamber

13. Side wall

14. Bottom panel (bottom)

15. Back wall

16. Unified rear wall panel

17. Front wall (frame with doors)

18. Transparent material of the front panel door

19. Shelves

20. Stand

21. Traverse

22. Thermal insulation protection (double-glazed window).

Collapsible refrigerated display case with convection cooling is carried out as follows.

Showcase cabinet 1 consists of refrigeration unit 2 and refrigeration chamber 8. The refrigeration unit includes compressor 3, condenser 4, evaporator 5 and fans 6, which are located on a single mounting panel 7. In turn, the mounting panel is located on the top panel 9 of the refrigerating chamber. The evaporator and fans are located on one side of the mounting panel and are enclosed in a heat-insulating casing 10. To ensure the convection exchange of the evaporator space under the heat-insulating casing and the refrigerating chamber, two through holes 11 are made on the mounting panel under the casing 11. The upper panel of the refrigerating chamber has similar coordinated through holes 12. ... The refrigerating chamber is made of side walls 13, a bottom panel or bottom 14, as well as a rear wall 15. In turn, the rear wall is made of a set of unified panels 16 arranged in horizontal rows. These panels and walls are designed into a refrigerating chamber by joining (fixing) on the racks 20. For fastening the lower and upper panels, as well as the side walls, the racks contain horizontal traverses 21, and the extreme racks contain two traverses, from the bottom and from the top of the rack, and the central racks only one upper traverse. Fastening of the walls and panels is carried out using fasteners, mainly threaded rivets. The front wall 17 of the refrigerating chamber is a frame with doors, and the door contains a transparent material 18, allowing visual inspection of the inner volume of the chamber. The transparent material is mainly a transparent glass unit, as well as, possibly, a plastic glass unit built into the door block. Under the frame with doors, there is a thermal insulation protection, which is mainly a transparent glass unit or a plastic glass unit. In some cases, thermal insulation protection can be made in an opaque or combined version, as well as in the form of a flat thermal insulation panel.

Inside the refrigerating chamber, shelves 19 for storing food are arranged in rows, which are supported by brackets attached to the racks. The described design of the display cabinet is an assembly unit that can be scaled horizontally along the line in accordance with the production need. The scaling factor is determined by production needs and is limited by the size of the room.

Example 1.

To make a refrigerated display cabinet with convection cooling, two end racks with perforations were fixed on the bottom panel, containing the lower and upper horizontal traverses directed along the location of the lateral sides. Then the legs with adjustable height were mounted on the outside, and the rear wall of two horizontal panels, the side walls and, finally, the top panel were fixed to the posts using threaded rivets. On the structure assembled in this way, a mounting panel with a refrigeration unit attached to it was installed on the top panel. The refrigeration unit includes a compressor, condenser, evaporator and fans. In this case, the evaporator and fans are located on one side of the mounting panel and are enclosed in a heat-insulating casing. To ensure convection exchange in the evaporator space under the heat-insulating casing and in the refrigerating chamber, two through holes are made on the mounting panel under the casing. Inside the refrigerating chamber, brackets in 5 vertical rows were fixed in perforations on racks, and wire shelves were placed on them. After that, the door frame is fastened from the front side of the cabinet and the doors are fastened with the help of special hinges from the front side of the cabinet, while the door contains a transparent glass unit limited by a technological edging. Under the doors, a glass panel is placed with a narrow strip as a technological panel that covers an additional opening. The side walls, top and bottom panels contain an insulating layer of polyurethane foam. The posts and traverses are made of 40 × 60 × 4 steel rectangular profile with perforations.

The dimensions of the display cabinet were 1875 mm, the volume was 1500 liters, the average temperature inside the loaded display cabinet was + 3 ° C, the temperature spread between the upper and lower shelves was 2 ° C, the power consumption was 8.5 kW / day. Ambient temperature + 25 ° С, relative humidity 60%.

Example 2.

To make a refrigerated display cabinet with convection cooling, three lower panels were laid out in a row on a plane, pre-mounted on these panels, legs with adjustable height and gluing the joining surfaces of the panels with foam tape. Then, along the edges of each panel, 2 end posts with perforations were fixed, containing the lower and upper traverses. Next, the racks installed on adjacent panels were pulled together using a screw connection, eliminating the gaps between the lower panels. After that, the back wall was mounted in horizontal rows, from unified panels, along its entire length, by attaching the panels to the racks. Then additional posts were attached to the rear panels with one horizontal traverse at the top point. All posts and panels were connected using threaded rivets. On the structure assembled in this way, 3 upper panels were installed from above, mirror-like to the lower panels, and on them, respectively, three cooling modules were installed in the form of mounting panels with fixed on each refrigeration unit. Each refrigeration unit includes a compressor, condenser, evaporator and fans. In this case, the evaporator and fans are located on one side of the mounting panel and are enclosed in a heat-insulating casing. To ensure convection exchange in the evaporator space under each heat-insulating casing and in the refrigerating chamber, two through holes are made on the mounting panel under the casing. Inside the refrigerating chamber, brackets in 5 vertical rows were fixed in perforations on racks, and wire shelves were placed on them. After that, the door frame is fixed from the front side of the cabinet and the doors are attached with the help of special hinges from the front side of the cabinet, while the door contains a transparent glass unit, limited by a technological edging. Under the doors, a glass panel is placed with a narrow strip as a technological panel that covers an additional opening. Side walls, top and bottom panels contain a heat-insulating layer of expanded polystyrene and contain strength amplifiers - embedded elements from a steel bent profile. Racks and traverses are made of steel rectangular profile 40 × 60 × 2.5 with perforations.

The dimensions of the display cabinet were 3 × 1875 = 5625 mm, the volume was 3 × 1500 = 4500 l, the average temperature inside the loaded display cabinet was + 3 ° С, the temperature spread between the upper and lower shelves was 2 ° С, the power consumption was 3 × 8, 5 = 25.5 kW / day. Ambient temperature + 25 ° С, relative humidity 60%.

Example 3.

To make a refrigerated display cabinet with convection cooling, the display cabinet was first assembled according to example 1, but without the right wall and frame with doors. Similarly, assembly units were assembled without both walls in the amount of 5. Then they connected all the assembly units in one row and put the right wall.

The assembled structure contained 12 refrigeration units. After that, the door frames were fixed and, with the help of special hinges on the front side of the cabinet, the doors themselves were fixed to the bottom panel corresponding to the width, while each door contained a transparent plastic glass unit in the entire width and height of the door. Side walls, top and bottom panels contained a heat-insulating layer of polyethylene foam and contained strength amplifiers - embedded elements from a steel bent profile. Racks and traverses are made of steel rectangular profile 40 × 60 × 2.5 with perforations.

The dimensions of the display cabinet were 6 × 1875 = 11250 mm, the volume was 6 × 1500 = 9000 l, the average temperature inside the loaded display cabinet was + 3 ° С, the temperature spread between the upper and lower shelves was 2 ° С, the power consumption was 6 × 8, 5 = 51 kW / day. Ambient temperature + 25 ° С, relative humidity 60%.

Example 4.

As a result of an accident in a display cabinet of 5 assembly units, the rear wall of two unified panels and the upper mounting panel of the middle assembly unit became unusable. The internal volume of the middle assembly unit was isolated with temporary partitions from the internal volume of other assembly units. Without disassembling the cabinet, we detached two panels of the back wall and replaced them with new ones. Then the refrigeration unit located on the damaged mounting panel was disconnected from the mains, disconnected from the top panel and removed together with the equipment installed on it. After that, a new mounting panel with a new refrigeration unit placed on it was installed on the staging location of the damaged panel.

Example 6.

To make a refrigerated display cabinet with convection cooling, two end racks with perforations were fixed on the bottom panel, containing the lower and upper horizontal traverses directed along the location of the lateral sides. Then the legs with adjustable height were mounted on the outside, and the rear wall of two horizontal panels, the side walls and, finally, the top panel were fixed to the posts using threaded rivets. On the structure assembled in this way, a mounting panel with a refrigeration unit attached to it was installed on the top panel. The refrigeration unit includes a compressor, condenser, evaporator and fans. In this case, the evaporator and fans are located on one side of the mounting panel and are enclosed in a heat-insulating casing. To ensure convection exchange in the evaporator space, two through holes are made on the mounting panel under the heat-insulating casing on the mounting panel. In the top panel, one hole is made to match the holes in the mounting panel and provide unhindered air access to the holes in the mounting panel. Inside the refrigerating chamber, brackets in 5 vertical rows were fixed in perforations on racks, and wire shelves were placed on them. After that, from the front side of the cabinet, the frame of the doors is fixed and the doors are attached with the help of special hinges from the front side of the cabinet, while the door contains a transparent glass unit limited by a technological edging. The side walls, top and bottom panels contain an insulating layer of polyurethane foam. The posts and traverses are made of 40 × 60 × 4 steel rectangular profile with perforations.

The dimensions of the display cabinet were 1875 mm, the volume was 1500 liters, the average temperature inside the loaded display cabinet was + 3 ° C, the temperature spread between the upper and lower shelves was 2 ° C, the power consumption was 8.5 kW / day. Ambient temperature + 25 ° С, relative humidity 60%.

Example 7.

To make a refrigerated display cabinet with convection cooling, the display cabinet was first assembled according to example 1, but without the right wall and frame with doors. Likewise, 11 assembly units were assembled without both walls. Then they connected all the assembly units in one row and put the right wall. The assembled structure contained 24 refrigeration units, two for each assembly unit. After that, the door frames were fixed and, with the help of special hinges on the front side of the cabinet, the doors themselves were fixed to the bottom panel corresponding in width, while each door contained a transparent plastic glass unit in the entire width and height of the door. The side walls, top and bottom panels contained a heat-insulating layer of polyethylene foam and contained strength-enhancing elements made of steel bent sections. Racks and traverses are made of steel rectangular profile 40 × 60 × 2.5 with perforations.

The dimensions of the display cabinet were 12 × 1875 = 22500 mm, the volume was 12 × 1500 = 18000 liters l, the average temperature inside the loaded display cabinet was + 3 ° С, the temperature spread between the upper and lower shelves was 2 ° С, the power consumption was 6 × 8 , 5 = 102 kW / day. Ambient temperature + 25 ° С, relative humidity 60%.

The above examples of examples should not be considered as limiting the scope of the utility model. On the contrary, variants, modifications and equivalents of the described examples are also possible within the scope of the rights set forth in the claims of the utility model.

The above description of the implementation of the utility model and examples of its implementation confirm the achievement of the claimed technical result in the process of implementing the utility model. They also show the causal relationship of essential features between themselves and the achieved technical result.

It also follows from the above description that the achievement of the technical result is possible only with the implementation of the entire set of essential features, which is also confirmed by the technical solution to the problem of implementing the utility model.

Claims (12)

1. Collapsible refrigeration display cabinet with convection cooling, containing at least one refrigeration unit, including a compressor, condenser, evaporator, as well as fan (s) and at least one refrigerating chamber with the possibility of visual access to its contents, which includes side walls, back and front walls, top and bottom panels made of heat-insulating materials, as well as shelves, characterized in that the refrigeration unit is mounted on a single flat mounting panel, which is located on top of the refrigerating chamber on its top panel, the evaporator and fan (s) are enclosed in a heat-insulating casing, and the part of the mounting panel enclosed in this casing, as well as the upper panel of the refrigerating chamber, have through holes matched in size and location for the implementation of forced convection exchange along the closed volume of the cabinet, the refrigerating chamber contains racks for fastening walls and panels, while the dimensions of the bottom and top panels, as well as the side walls, are respectively unified, the bottom and top panels as well as the refrigeration unit are scalable to the length of the display cabinet, the back wall is made in horizontal rows by a set of unified panels and is scalable along the length of the display cabinet, scaling of unified structural elements is carried out by fixing the edges of these elements on mating racks, the front wall is made of a frame with doors, under which thermal insulation protection is located at the bottom of the cabinet, the doors include transparent material, and the frame with doors can be scaled in a row along the length of the display cabinet by linear placement of additional frames with doors. 2. A collapsible refrigerated display cabinet according to claim 1, characterized in that the mounting panel has mounting holes for mounting refrigeration equipment. 3. A collapsible refrigerated display cabinet according to claim 1, characterized in that the extreme racks of the refrigerating chamber contain two horizontal traverses, one of which is located at the top of the rack, and the other at the bottom. 4. Collapsible refrigerated display cabinet according to claim 1, characterized in that the central pillars of the refrigerating chamber contain one horizontal traverse, which is located at the upper point of the rack. 5. Collapsible refrigerated display cabinet according to claim 1, characterized in that the racks are made of a structural perforated profile. 6. Collapsible refrigerated display cabinet according to claim 1, characterized in that the walls and panels are fastened to the racks using threaded rivets. 7. Collapsible refrigerated display case according to claim 1, characterized in that the rear wall is made in two horizontal rows.

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