CN220786568U - Movable interlayer insulation can - Google Patents

Abstract

The utility model discloses a movable interlayer insulation box which comprises a box body and a cover body, wherein the box body is provided with an interlayer, and the interlayer is movably arranged in the box body in a turnover mode. The utility model is provided with the interlayer, so that different spaces can be formed in the box body, and the storage of fish is taken as an example for illustration. An ice layer can be arranged in each space in the box body, so that the problem that the distribution of cold sources is uneven due to the fact that ice in the box body continuously moves to the top of the box body due to light weight is avoided. In addition, the interlayer is arranged, so that the problem of excessive extrusion caused by multiple pressure born by the fish can be avoided. The incubator of the utility model is particularly suitable for fresh-keeping of foods such as fish and the like. Can avoid fish spoilage caused by insufficient cold source and excessive extrusion. Prolonging the fresh-keeping period of fish.

Description

Movable interlayer insulation can

Technical Field

The utility model relates to an insulation box, in particular to a movable interlayer insulation box.

Background

In daily life, the thermal insulation container is generally used for transporting and storing aquatic products and the like, and common thermal insulation containers include a thermal insulation box, a thermal insulation cabinet, a thermal insulation container with a refrigerating unit (such as a refrigerator and a freezer), and the like, (1) the conventional thermal insulation box (with an upward opening) is internally provided with a lack of separation layers, for example, when fish is stored, the fish is excessively extruded with the fish, and the fish is easy to crush and stink. In addition, ice is lighter than fish, and easily moves towards the top of case, leads to the cold source of box inside not enough, leads to the local high temperature of fish for the bacterium breeds too soon, leads to the fish putrefaction.

(2) The taking and placing opening of the heat preservation cabinet is arranged on the side elevation, and the heat preservation cabinet cannot be suitable for a use scene of taking water ice as a cold source (without a refrigerating unit) for storing articles, because the heat preservation cabinet (the taking and placing opening is arranged on the side elevation) can cause water overflow and the like after the water ice is melted into water;

(3) The heat preservation container with the refrigeration source such as the refrigerator has high use cost and inconvenient movement, and a power supply is required to be equipped when the heat preservation container is used, so that a plurality of use limitations exist.

In view of the above, the present inventors have conducted intensive studies and have made the present utility model.

Disclosure of Invention

The utility model aims to provide an insulation box which is convenient and flexible to use and is suitable for transportation and storage by taking water ice and the like as cold sources.

The utility model provides a movable interlayer insulation can, includes box and lid, the inside of box is equipped with the interlayer, the inside of box corresponds one side of interlayer is formed with the overhead layer, the interlayer with can turn over the mode movable mounting in the inside wall of box.

Further, the interlayer comprises a first layer plate and a second layer plate, the first layer plate comprises a first connecting end and a first splicing end, the second layer plate comprises a second connecting end and a second splicing end, the first connecting end and the second connecting end are respectively hinged to the inner side wall of the box body, and the first connecting end and the second connecting end are oppositely arranged.

Further, the first splicing end and the second splicing end are spliced together to form a splicing seam, stop blocks are respectively arranged at two ends of the box body corresponding to the length direction of the splicing seam, the first laminate and the second laminate are positioned in the same plane after being spliced, the stop blocks are positioned below the plane, and the stop blocks are arranged next to the first splicing end and the second splicing end.

Further, the box body is pre-buried to have a plurality of groups of fastener that are used for installing the interlayer, a plurality of groups of fastener set up the difference in height.

Further, the width of the splice seam is 20mm.

Further, the box body is provided with two or more layers of the interlayer, and the overhead layer is formed between the interlayer.

Further, the first connecting end is provided with concave positions, the concave positions are correspondingly provided with rotating shafts, the rotating shafts are provided with hinges, the hinges are fixed on the inner side walls of the box body, the first connecting end is provided with at least two concave positions, the second connecting end is identical to the first connecting end in structure, and the concave positions are correspondingly provided with hinges one by one.

Further, the hinge is provided with a rotating shaft groove, the rotating shaft is arranged in the rotating shaft groove, the hinge is provided with fastening holes, a plurality of groups of fasteners with different setting heights are embedded in the box body, and the fastening holes are correspondingly arranged with the fasteners.

Further, a sealing ring is arranged between the box body and the cover body, a high-low order matching structure is formed between the cover body and the box body, and the sealing ring is arranged at a position corresponding to a low order of the high-low order matching structure.

Further, an RFID ultra-high frequency temperature measuring chip is arranged on the inner side wall of the box body;

the movable interlayer insulation can is further provided with a control box body, the control box body comprises an outer shell body, and a control module, an RFID ultrahigh frequency card reading chip, a power module and a wireless communication module which are integrally designed on a circuit board, wherein the circuit board is arranged in the outer shell body, the outer shell body is embedded on the outer side wall of the box body, the RFID ultrahigh frequency card reading chip is connected with the RFID ultrahigh frequency temperature measuring chip through radio frequency identification communication, the RFID ultrahigh frequency card reading chip and the wireless communication module are respectively and electrically connected with the control module in a bidirectional manner, the control module is connected with an Internet of things cloud management platform through wireless communication, and the power module provides a working power supply for each module in the control box body;

the control box body further comprises a positioning module, and the positioning module is in bidirectional electric connection with the control module.

After the technical scheme is adopted, the movable interlayer insulation can has the following beneficial effects: the interlayer is arranged to enable different spaces to be formed inside the box body, and the storage of fish is taken as an example. An ice layer can be arranged in each space in the box body, so that the problem that the distribution of cold sources is uneven due to the fact that ice in the box body continuously moves to the top of the box body due to light weight is avoided. In addition, the interlayer is arranged, so that the problem of excessive extrusion caused by multiple pressure born by the fish can be avoided. The incubator of the utility model is particularly suitable for fresh-keeping of foods such as fish and the like. Can avoid fish spoilage caused by insufficient cold source and excessive extrusion. Prolonging the fresh-keeping period of fish. Compared with the traditional heat preservation cabinet, the heat preservation box can be used for preserving articles with water and ice (described with fish as an example), and is more suitable for rapidly loading and unloading fish, for example, when the heat preservation box is used, the heat preservation box can be used for rapidly dumping, the interlayer can be automatically opened during dumping, the fish can be rapidly dumped, and the fish can be rapidly loaded and unloaded layer by layer during boxing, so that automatic rapid loading and unloading can be realized. Compared with a heat preservation container with a refrigerating unit, the heat preservation box is not influenced by the use environment such as an external power supply, has good use flexibility, and is wide in application range, economical and energy-saving.

Drawings

FIG. 1 is a schematic diagram of an exploded structure of a movable compartment incubator of the present utility model;

FIG. 2 is a cross-sectional view of the movable compartment incubator of the present utility model;

FIG. 3 is a cross-sectional view of the movable compartment incubator of the present utility model (differing from FIG. 2 in the structure of the hinge);

FIG. 4 is a schematic view of the mounting structure of the hinge of the present utility model;

fig. 5 is a schematic block diagram of a management system according to the present utility model.

In the figure:

a box body-1; a cover body-2;

an interlayer-3; a first laminate-31;

a first connection terminal-311; a first split end-312;

a second laminate-32; a second connection end-321;

a first split end-322; splice seam-4;

stop block-5; a seal ring-61;

high-low order matching structure-62; an RFID ultra-high frequency temperature measuring chip-71;

a control module-72; an RFID ultrahigh frequency card reading chip-73;

a power module-74; a wireless communication module-75;

the cloud management platform-76 of the Internet of things; a positioning module-77;

concave position-81; a rotating shaft-82;

a hinge-83; a rotating shaft groove-831;

fastening holes-832.

Detailed Description

In order to further explain the technical scheme of the utility model, the utility model is explained in detail by specific examples.

The utility model relates to a movable interlayer insulation box, which is shown in figures 1-3, and comprises a box body 1 and a cover body 2, wherein an opening of the box body 1 faces upwards. The inside of box 1 is equipped with interlayer 3, and the inside of box 1 corresponds the one side of interlayer 3 and is formed with the empty space layer. The interlayer 3 is movably arranged in the box body 1 in a turnover way. In this embodiment, the barrier layer 3 is a split barrier layer 3. A stop block 5 is arranged below the interlayer 3. The stop block 5 is correspondingly arranged at the opening and closing position and used for supporting the supporting stability of the interlayer 3.

Specifically, the interlayer 3 includes a first laminate 31 and a second laminate 32, the first laminate 31 includes a first connection end 311 and a first split end 312, the second laminate 32 includes a second connection end 321 and a second split end 322, the first connection end 311 and the second connection end 321 are respectively hinged on the inner side wall of the case 1 through hinges, and the first connection end 311 and the second connection end 321 are installed relatively. The hinge is a conventional hinge in the market, so that the interlayer can be turned over and closed, and the detailed description is omitted.

The first splicing end 312 and the second splicing end 322 are spliced together to form a splicing seam 4, and two ends of the box body 1 corresponding to the length direction of the splicing seam 4 are respectively provided with the stop blocks 5. The first ply 31 and the second ply 32 are joined to lie in the same plane, with the stop 5 located below the plane, and the stop 5 located immediately adjacent (in the same plane as) the first and second joined ends 312, 322.

In this embodiment, the first laminate 31 and the second laminate 32 are assembled to be positioned on the same horizontal plane. The first layer plate 31 and the second layer plate 32 after the stop block 5 is arranged to cover are not only provided with the function of auxiliary support, but also provided with the stop limiting function, so that the first layer plate 31 and the second layer plate 32 can be prevented from excessively moving downwards (namely, the split ends are prevented from moving downwards to be relatively positioned below the plane) under the pressure effect, the layer plates are prevented from excessively deforming, the normal use of the interlayer 3 is influenced, and the service life of the interlayer 3 is prolonged.

The incubator of the utility model is particularly suitable for transportation and storage of frozen foods (such as fish, meat and the like).

According to the movable interlayer insulation box, the interlayer 3 is arranged, so that different spaces can be formed in the box body 1. The following will take the stored fish as an example. An ice layer can be arranged in each space in the box body 1, so that the problem that the distribution of cold sources is uneven due to the fact that ice in the box body continuously moves to the top of the box body 1 due to light weight is avoided. In addition, the interlayer 3 is arranged to form an overhead layer, so that the problem of excessive extrusion caused by multiple pressure born by the fish can be avoided. The incubator of the utility model is particularly suitable for the storage and preservation of (chilled) foods such as fish, meat and the like. Can avoid fish spoilage caused by insufficient cold source and excessive extrusion. Prolonging the fresh-keeping period of fish.

In the use process, for example, when the device is used for dumping, the interlayer 3 can be automatically opened, and the operation is very convenient.

As a preferred embodiment, the case 1 is pre-embedded with several sets of fasteners a for mounting the barrier 3. The sets of fasteners a are arranged at different heights. In this embodiment, the fastener a is a nut. The fasteners a are arranged at different height positions, so that a user can select conveniently according to own needs, and the mounting height of the interlayer can be flexibly selected. In addition, the interlayer 3 can be additionally arranged according to the self requirement.

As a preferred embodiment, the width of the splice seam is 20mm. In the utility model, the width of the splicing seam can be set according to actual requirements. The width of the splice is sufficient to facilitate opening (finger manipulation) of the barrier.

As a preferred embodiment, the first ply 31 and/or the second ply 32 are provided with a pull cord. When the laminate is to be opened, the corresponding laminate can be opened by pulling upwards by means of the pull rope.

As a preferred embodiment, the case 1 is provided with two or more barrier layers 3. An overhead layer is formed between the spacers 3.

As a preferred embodiment, as shown in fig. 2, the first connecting end 311 is provided with a concave portion 81, and the concave portion 81 is correspondingly provided with a rotating shaft 82. The rotating shaft 82 may be a rotating shaft, the concave portion 81 is adapted to the rotating shaft 82, and two ends of the rotating shaft 82 are correspondingly disposed at two opposite ends of the concave portion 81. Alternatively, the rotating shaft 82 is two shaft sections, and the two shaft sections are correspondingly installed at two opposite ends of the concave portion 81.

The rotary shaft 82 is equipped with a hinge 83, and the hinge 83 is fixed to the inner side wall of the case 1. The first connecting end 311 is provided with at least two concave positions 81, the second connecting end 321 has the same structure as the first connecting end 311, and the concave positions 81 are provided with hinges 83 in one-to-one correspondence.

The hinge 83 is provided with a rotating shaft groove 831, the rotating shaft 82 is movably arranged in the rotating shaft groove 831, the hinge 83 is provided with a fastening hole 832, the box body 1 is pre-embedded with a plurality of groups of fasteners a with different heights, and the fastening hole 832 is correspondingly arranged with the fasteners a. In this embodiment, the hinge 83 is a common hinge (refer to fig. 2), the hinge is a metal member, and fastening holes 832 are formed on both sides of the hinge 83 in the rotation shaft slot 831.

Further, in order to prevent the hinge from rubbing against stored articles, the hinge 83 is a plastic member having a certain thickness (a thickness greater than the depth of the hinge grooves 831), and the hinge 83 is formed with a slot hole at the upper portion thereof to form the hinge grooves 831, as shown in fig. 3 and 4. The lower part of the hinge 83 is provided with a slot hole to form a fastening hole 832, the shape and the size of the fastening hole 832 are respectively matched with those of a locking piece (the locking piece in the embodiment can be an inner hexagon screw), and the fastening hole 832 is a T-shaped hole. The hexagon socket head cap screw is embedded in the fastening hole 832 and locked with the nut embedded in the box 1. The end of the socket head cap screw is flush with the outer surface of the hinge or is located in the fastener hole 832. The corners of the hinge 83 are rounded corners, the rotating shaft grooves 831 are positioned on the upper portion of the hinge 83, and the fastening holes 832 are positioned on the lower portion of the hinge, namely, the inner hexagon screws are locked on the lower portion of the hinge 83.

As a preferred embodiment, a sealing ring 61 is provided between the case 1 and the cover 2.

Further, a high-low level matching structure 62 is formed between the cover 2 and the case 1, and the seal ring 61 is disposed corresponding to the low level position of the high-low level matching structure 62. In this way, the sealability between the cover 2 and the case 1 can be improved.

As a preferred embodiment, as shown in fig. 5, the inner side wall of the case 1 is provided with an RFID ultra-high frequency temperature measuring chip 71.

The movable interlayer insulation can is further provided with a control box body, the control box body comprises an outer shell body, and a control module 72, an RFID ultrahigh frequency card reading chip 73, a power module 74 and a wireless communication module 75 which are integrally designed on a circuit board, the circuit board is arranged in the outer shell body, the outer shell body is embedded on the outer side wall of the box body 1, the RFID ultrahigh frequency card reading chip 73 and the RFID ultrahigh frequency temperature measuring chip 71 are connected through radio frequency identification communication, the RFID ultrahigh frequency card reading chip 73 and the wireless communication module 75 are respectively connected with the control module 72 in a bidirectional electric mode, the control module 72 is connected with the Internet of things cloud management platform 76 through wireless communication, and the power module 74 provides working power for all modules in the control box body.

The control box body further comprises a positioning module 77, and the positioning module 77 is in bidirectional electrical connection with the control module 72.

The movable interlayer insulation can provide temperature monitoring and the like of a cold-chain logistics insulation container, the box body 1 can monitor the RFID ultrahigh frequency temperature measuring chip 71 through the circuit board, the measured temperature in the box body 1 is uploaded to the Internet of things cloud management platform 76 through the wireless communication module 75 by the control module 72, and the Internet of things cloud management platform 76 receives the uploaded information and then displays, performs data statistics, analyzes, early warning or issues corresponding control instructions and the like. The control means are conventional.

The power module 74 employs a battery. The control module 72 is specifically a general-purpose MCU module with a program memory embedded therein. The software system embedded in the control module 72 can be programmed according to actual requirements. The control module 77 may employ an MCU controller model HC32L136K8 TK. The wireless communication module 75 is embodied as an NB-IOT module. The positioning module 77 is specifically a GPS/beidou positioning module. In the utility model, each module adopts the existing corresponding module. Besides the specific modules, other modules can be adopted to realize corresponding functions.

In this embodiment, the case 1 and the cover 2 are both insulation boards. And the heat insulation layer is formed by filling heat insulation materials in the heat insulation board. Polyurethane can be used as the heat insulating material. The heat insulating layer is coated with heat insulating sheet. The heat-insulating sheet comprises a double-layer inner wall sheet and a double-layer outer wall sheet, and the heat-insulating sheet adopts carbon fiber prepreg epoxy resin cloth. The RFID ultra-high frequency temperature measurement chip 71 is disposed in the interlayer between the inner wall sheets of the double layer. The temperature inside the case 1 is accurately monitored.

The embedded fastening member a (such as a nut) may be disposed between the heat insulating layer and the inner wall sheet, and the inner wall sheet may be disposed between the fastening member a and the inside of the case 1. When the interlayer is installed, the position of the fastener a can be found by touching by hands, then a pointed tool and the like are used for taking holes at the positions corresponding to the fastener a, and the screw can be locked on the fastener a (nut).

The above examples and drawings are not intended to limit the form or form of the present utility model, and any suitable variations or modifications thereof by those skilled in the art should be construed as not departing from the scope of the present utility model.

Claims (10)

1. A movable interlayer insulation can is characterized in that: the novel box comprises a box body and a cover body, wherein the box body is provided with an opening which is opened upwards, an interlayer is arranged in the box body, an overhead layer is formed in one side of the box body, which corresponds to the interlayer, and the interlayer is movably mounted on the inner side wall of the box body in a turnover mode.

2. The movable barrier incubator of claim 1, wherein: the lower part of the interlayer is provided with a stop block for supporting the interlayer to support the interlayer, and the stop block is correspondingly arranged at the opening and closing part of the interlayer.

3. The movable barrier incubator of claim 2, wherein: the interlayer comprises a first layer plate and a second layer plate, the first layer plate comprises a first connecting end and a first splicing end, the second layer plate comprises a second connecting end and a second splicing end, the first connecting end and the second connecting end are respectively hinged to the inner side wall of the box body, and the first connecting end and the second connecting end are oppositely arranged.

4. A mobile insulating barrier as claimed in claim 3, wherein: the first splicing end and the second splicing end are spliced together to form a splicing seam, the two ends of the box body corresponding to the length direction of the splicing seam are respectively provided with the stop blocks, the first laminate and the second laminate are spliced and then located in the same plane, and the stop blocks are located below the plane.

5. The movable barrier incubator of claim 1, wherein: the side wall of the box body is pre-buried with a plurality of groups of fasteners used for installing the interlayer, and the setting heights of the fasteners are different.

6. The movable barrier incubator of claim 1, wherein: the box is provided with two or more layers of interlayer, and the overhead layer is formed between the interlayer.

7. A mobile insulating barrier as claimed in claim 3, wherein: the first connecting end is provided with concave positions, the concave positions are correspondingly provided with rotating shafts, the rotating shafts are provided with hinges, the hinges are fixed on the inner side walls of the box body, the first connecting end is provided with at least two concave positions, the second connecting end is identical to the first connecting end in structure, and the concave positions are correspondingly provided with hinges one by one.

8. The movable barrier incubator of claim 7, wherein: the hinge is provided with a rotating shaft groove, the rotating shaft is arranged in the rotating shaft groove, the hinge is provided with fastening holes, a plurality of groups of fasteners with different setting heights are embedded in the box body, and the fastening holes are correspondingly arranged with the fasteners.

9. The movable barrier incubator of claim 1, wherein: the sealing ring is arranged between the box body and the cover body, a high-low order matching structure is formed between the cover body and the box body, and the sealing ring is arranged at a position corresponding to the low order of the high-low order matching structure.

10. The movable barrier incubator of claim 1, wherein: an RFID ultrahigh frequency temperature measuring chip is arranged on the inner side wall of the box body;

the movable interlayer insulation can is further provided with a control box body, the control box body comprises an outer shell body, and a control module, an RFID ultrahigh frequency card reading chip, a power module and a wireless communication module which are integrally designed on a circuit board, wherein the circuit board is arranged in the outer shell body, the outer shell body is embedded on the outer side wall of the box body, the RFID ultrahigh frequency card reading chip is connected with the RFID ultrahigh frequency temperature measuring chip through radio frequency identification communication, the RFID ultrahigh frequency card reading chip and the wireless communication module are respectively and electrically connected with the control module in a bidirectional manner, the control module is connected with an Internet of things cloud management platform through wireless communication, and the power module provides a working power supply for each module in the control box body;

the control box body further comprises a positioning module, and the positioning module is in bidirectional electric connection with the control module.