CN212213123U - Storage cabinet - Google Patents

Abstract

The utility model relates to a storage cabinet is equipped with a plurality of open-ended storage check forward, is equipped with the detachable drawer in the storage check, and drawer open-top is furnished with the detachable roof pad for the interior roof of storage check, and the drawer is packed into then and is enclosed into storage space with the roof pad in the storage check. This cabinet is furnished with detachable roof pad for the interior roof of storage check, and the drawer is packed into then in the storage check and is enclosed into storage space with the roof pad for article in the drawer can not touch the storage check roof, thereby keeps the storage check roof clean, and roof pad and drawer can be dismantled respectively and wash, make the inside health of cabinet keep.

Description

Storage cabinet

Technical Field

The utility model relates to a storage device especially relates to a cabinet with a plurality of storage check.

Background

In order to store a plurality of foods in different categories, some refrigerators are provided with a plurality of storage compartments, each of which is provided with a detachable drawer, and a user can detach the drawer for cleaning. However, the food placed in the drawer may contact the top wall of the storage compartment, causing the top wall of the storage compartment to be easily stuck with the food. When the space of a single storage grid is set to be smaller, the top wall of the storage grid is difficult to clean, some places are easy to be cleaned out, and food stuck on the top wall of the storage grid is easy to rot for a long time to breed bacteria.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is how to keep the health of roof in the storage check.

In order to solve the technical problem, the utility model discloses a storage cabinet is equipped with a plurality of open-ended storage check forward, is equipped with the detachable drawer in the storage check, and drawer open-top is furnished with the detachable roof pad for the interior roof of storage check, and the drawer is packed into then and is enclosed into storage space with the roof pad in the storage check.

Further, an inner case opened forward is included, the inner case is detachably mounted in the storage compartment, the drawer is mounted in the inner case from the opening of the inner case, and the top wall of the inner case serves as the top wall pad.

Further, the storage cells are arranged in columns.

Further, each storage check sharing locking mechanism in one row, specifically, locking mechanism includes the montant and is used for controlling the vertical control assembly that the montant vertically moved, the montant is equipped with the inner shell in the storage check that chucking spare corresponds with the chucking in the position department that corresponds with every storage check, the vertical carry of montant makes the inner shell of the storage check of packing into by the chucking spare chucking, the vertical setting of montant makes chucking spare unblock correspond the chucking of inner shell.

Further, the vertical rod is located behind the containing position of the inner shell of the storage grid, and the clamping piece extends towards the containing position of the inner shell.

Furthermore, a through hole is formed in the rear portion of each storage grid in one row, and the vertical rod penetrates through the through holes of the storage grids.

Further, the clamping piece comprises a buckle extending towards the inner shell, and the inner shell is provided with a clamping piece corresponding to the buckle on the bottom wall or the top wall.

Furthermore, the clamping piece further comprises a carry spring for applying a carry force to the clamping piece, the clamping piece and/or the clamping piece are/is provided with a guide inclined plane, the vertical rod is in a carry state, in the process that the inner shell is arranged in the storage grid, under the guide effect of the guide inclined plane, the clamping piece is pushed by the inner shell in a squeezing mode so as to offset due to the fact that the carry force of the carry spring is overcome, and then the clamping piece is buckled by returning under the action of the carry force of the carry spring.

Further, the vertical control assembly includes a cam mechanism and a spring that provides a locking force for the cam mechanism.

Further, the front end of the bottom wall of the inner shell extends downwards and then backwards to form a clamping positioning piece, and the clamping positioning piece and the bottom wall of the inner shell clamp the bottom wall of the storage grid together.

Furthermore, the edge of the front side wall of the drawer is surrounded by a sealing strip to seal a gap between the front side wall of the drawer and the opening of the inner shell.

Further, this intelligent cabinet is the intelligent refrigerator-freezer of storage food.

This cabinet is furnished with detachable roof pad for the interior roof of storage check, and the drawer is packed into then in the storage check and is enclosed into storage space with the roof pad for article in the drawer can not touch the storage check roof, thereby keeps the storage check roof clean, and roof pad and drawer can be dismantled respectively and wash, make the inside health of cabinet keep.

Drawings

FIG. 1 is a schematic view of the structure of a first embodiment of a smart ice bin;

FIG. 2 is a schematic structural view of the food plate storage module of FIG. 1 with the trays in the two storage compartments above the first row hidden;

FIG. 3 is a schematic structural view of the handleless cup storage module of FIG. 1 with handleless cups hidden from view in the rightmost handleless cup storage location of the first row;

FIG. 4 is a schematic side front view of the food plate storage module of the second embodiment of the intelligent ice chest;

FIG. 5 is a side rear view of the food plate storage module of FIG. 4;

FIG. 6 is a side rear perspective view of the food plate storage module of FIG. 4 with the locking mechanism, inner housing and tray concealed;

FIG. 7 is a schematic structural view of the inner case in the food plate storage module of FIG. 4 in a state of being set right;

FIG. 8 is a schematic structural view of the inner case of FIG. 7 in an inverted state;

FIG. 9 is a schematic structural view of the locking mechanism of FIG. 5;

FIG. 10 is an enlarged view at A in FIG. 9, showing the construction of the retainer;

FIG. 11 is a schematic structural view of the tray of FIG. 2 or FIG. 4;

FIG. 12 is a schematic view of a stand-up smart cooler.

Reference numerals: 100. a cabinet body; 10. a food plate storage module; 11. a storage case; 12. a holding tray; 121. a tray body; 122. a handle; 1221. an upper plate; 1222. a lower plate; 123. a light-reflecting coating; 124. a sealing strip; 13. a storage cell; 131. a through hole; 14. an LED lamp; 15. a pressure sensor; 16. an inner shell; 161. concave holes; 162. clamping a positioning piece; 17. a locking mechanism; 171. a vertical rod; 172. a cam mechanism; 173. a bottom spring; 174. a fixed block; 175. a retainer; 1751. a shaft sleeve; 1752. a carry spring; 1753. a bottom block; 1754. buckling; 20. a stewing cup storage module; 21. a storage case; 22. stewing a handleless cup; 23. storing the stewing cup; 24. an annular LED lamp; 25. a pressure sensor; 30. a refrigerator.

Detailed Description

The invention will be further explained with reference to the drawings and the detailed description, wherein the protection sought is mainly related to the second embodiment in fig. 4 to 11.

First embodiment

The intelligent ice chest of the first embodiment is shown in fig. 1, and comprises a cabinet 100, wherein a food plate storage module 10, a stewing cup storage module 20, a refrigerator 30 and a controller for controlling the operation of related electronic devices in each module are arranged in the cabinet 100. The controller activates chiller 30 to provide cooling to storage modules 10, 20. There are a plurality of the food plate storage module 10 and the stewpot storage module 20. The inner wall of the cabinet 100 is provided with slide rails (not shown) corresponding to the food plate storage modules 10 and the handleless cup storage modules 20 one by one, the outer side walls of the food plate storage modules 10 and the handleless cup storage modules 20 are provided with corresponding slide blocks (not shown), and the slide blocks are clamped into the corresponding slide rails to form a moving mechanism, so that the food plate storage modules 10 and the handleless cup storage modules 20 can be moved out of the cabinet 100 along the slide rails in a sliding manner, as shown in fig. 1, one food plate storage module 10 and one handleless cup storage module 20 are in a moving-out state.

As shown in fig. 2, the food plate storage module 10 includes a storage case 11, a plurality of storage compartments 13 are defined on the storage case 11, the storage compartments 13 are arranged in a plurality of rows, and each storage compartment 13 is provided with a drawer-type tray 12. Each storage grid 13 has a unique number, the storage shell 11 is provided with LED lamps 14 corresponding to the storage grids 13 one by one, and the LED lamps 14 surround the exposed grid opening edge of the corresponding storage grid 13 and are electrically connected with the controller. The bottom of the storage grid 13 is provided with a pressure sensor 15 corresponding to the number of the storage grid, and the pressure sensor 15 is electrically connected with the controller. If food needs to be stored, the food plate storage module 10 is pulled out of the cabinet body 100, then the empty storage tray 12 is pulled out of the storage grid 13, so that the food is placed in the storage tray 12, then the storage tray 12 filled with the food is placed in the storage grid 13, at the moment, the pressure sensor 15 at the bottom of the storage grid 13 stored with the food sends a corresponding pressure detection signal to the controller, and the controller can determine which storage grid 13 stores the food according to the pressure value of the received pressure detection signal, so that the name of the food and the number of the corresponding storage grid 13 are recorded. The food name is obtained by inputting by a user using an additionally provided input device (for example, a touch screen provided on the cabinet 100 and communicatively connected to the controller, or a user terminal capable of communicating with the controller), or by scanning a two-dimensional code or a bar code on the food package by using an additionally provided scanning device. When a user needs to take out food, the controller determines the number of the storage grid 13 corresponding to the user according to the name of the food to be taken by the user, so that the LED lamp 14 of the storage grid 13 corresponding to the number is controlled to be turned on, and thus, after the user pulls the plate storage module 10 out of the cabinet body 100, the position of the storage grid 13 where the food to be taken is located can be quickly determined according to the turned-on LED lamp 14.

The stewing cup storage module 20 comprises a storage shell 21, wherein a plurality of stewing cup storage positions 23 which are horizontally arranged in a plurality of rows are arranged on the storage shell 21, and the stewing cup storage positions 23 are recessed relative to the periphery so as to be used for placing stewing cups 22 and prevent the stewing cups 22 from sliding, as shown in fig. 3. Each stewing cup storage bit 23 has a unique number, an annular LED lamp 24 which corresponds to the stewing cup storage bits 23 one by one is arranged on the storage shell 21, and the annular LED lamp 24 surrounds the exposed peripheral edge of the corresponding stewing cup storage bit 23 and is electrically connected with the controller. The bottom of the stewing cup storage bit 23 is provided with a pressure sensor 25 corresponding to the number of the stewing cup storage bit, and the pressure sensor 25 is electrically connected with the controller. If food needs to be stored, the stewing cup storage module 20 is pulled out of the cabinet body 100, then the stewing cup 22 filled with food is placed in the stewing cup storage position 23, the pressure sensor 25 sends a pressure detection signal to the controller, and the controller can determine which stewing cup storage position 23 stores food according to the pressure value of the received pressure detection signal, so that the name of the food and the number of the corresponding stewing cup storage position 23 are recorded. If the user needs to take out food, the controller determines the number of the corresponding stewing cup storage bit 23 according to the name of the food to be taken by the user, so that the annular LED lamp 24 of the stewing cup storage bit 23 corresponding to the number is controlled to be turned on, and therefore after the user pulls out the stewing cup storage module 20 from the cabinet body 100, the position of the stewing cup storage bit 23 where the food to be taken is located can be rapidly determined according to the turned-on annular LED lamp 24.

The tray 12, as shown in fig. 11, includes a tray body 121 for holding food, and a handle 122 is extended from the front side of the tray body 121. The upper plate 1221 of the handle 122 extends obliquely upward and the lower plate 1222 extends obliquely downward to form a shape similar to an open bird mouth, so that a good support point can be provided for a user when the user holds the tray 12 with the hand, and the user can apply force to hold the tray 12 stably.

Second embodiment

Compared with the first embodiment, the intelligent ice chest of the second embodiment is different from the intelligent ice chest of the first embodiment only in the structure of the tray 12 in the food plate storage module 10 and the assembly manner between the tray 12 and the storage grid 13, so the following description is only directed to the structure of the tray 12 and the assembly structure between the tray 12 and the storage grid 13, and other structures are the same as the first embodiment and are not repeated.

The food plate storage module 10 of the intelligent ice chest of the second embodiment is shown in fig. 4, each storage compartment 13 is provided with an inner shell 16 as shown in fig. 7, and the inner shells 16 in each storage compartment 13 of each column are detachably mounted in the corresponding storage compartment 13 by a locking mechanism 17 as shown in fig. 9. As shown in fig. 5, the locking mechanism 17 is installed at the rear side of the storage compartment 13, and the locking mechanism 17 includes a vertical rod 171, a cam mechanism 172 and a bottom spring 173, wherein the cam mechanism 172 and the bottom spring 173 form a vertical control assembly. The cam mechanism 172 is hinged on the top end of the vertical rod 171 and is located above the top wall of the topmost storage cell, the fixing block 174 at the bottom end of the vertical rod 171 fixes the bottom spring 173, and the bottom spring 173 is sleeved on the bottom end of the vertical rod 171 and compressed between the fixing block 174 and the bottom wall of the first storage cell 13 below so that the cam mechanism 172 abuts against the upper surface of the top wall of the topmost storage cell. The vertical bar 171 is provided with a retainer 175 at a position corresponding to the bottom wall of each cell 13, and a through hole 131 is opened at the rear of each cell 13 in a row, as shown in fig. 6, and the vertical bar 171 passes through the through hole of each cell. The retainer 175 is shown in fig. 10 and includes a sleeve 1751, a carry spring 1752 for applying a carry force to the sleeve 1751, and a bottom block 1753 fixed to the vertical rod 171. Shaft sleeve 1751 and carry spring 1752 all overlap on montant 171, carry spring 1752 is located between shaft sleeve 1751 and bottom block 1753, shaft sleeve 1751 bottom leaves the space that supplies carry spring 1752 to get into (for showing the structure of chucking spare 175 more clearly in fig. 10, show shaft sleeve 1751 and carry spring 1752 separation, under actual assembled state, carry spring 1752 upper portion is located the space of shaft sleeve 1751 bottom and is sheltered from), shaft sleeve 1751 lateral wall stretches out outwards and forms buckle 1754, the buckle 1754 front end is equipped with guide inclined plane 1755. Correspondingly, as shown in fig. 8, the inner housing 16 has a concave hole 161 at the rear end of the bottom wall as a latch, which corresponds to the latch 1754.

Before the inner housing 16 is mounted, the cam mechanism 172 is pulled perpendicular to the vertical rods 171 to slightly raise the vertical rods 171, during which the retaining blocks 174 press the bottom springs 173 upward to further compress them between the retaining blocks 174 and the bottom wall of the underlying first storage compartment 13, as shown in fig. 5. Then, the inner case 16 is pushed into the storage cell 13, and in the process, under the guiding action of the guiding inclined plane 1755, the buckle 1754 drives the shaft sleeve 1751 to downwards extrude the carry spring 1752 due to the pushing of the bottom wall of the inner case 16, so that the carry force of the carry spring 1752 is overcome to downwards move, and then the carrying force of the carry spring 1752 returns to the original position to be clamped into the concave hole 161. If the inner shell 16 needs to be disassembled, the cam mechanism 172 needs to be pulled until the cam mechanism 172 and the vertical rod 171 are located on the same axis, so that the vertical rod 171 moves down to the original position, and thus the buckle 1754 on the vertical rod 171 moves down to be separated from the concave hole 161, and the inner shell 16 can be pulled out of the storage compartment 13. As shown in fig. 7 or 8, the front end of the bottom wall of the inner housing 16 extends downward and then rearward out of the holding fixture 162, a gap 163 is left between the holding fixture 162 and the bottom wall of the inner housing 16, and when the inner housing 16 is pushed into the storage compartment 13, the bottom wall of the storage compartment 13 is clamped by being clamped in the gap 163, so that the inner housing 16 is stably positioned in the storage compartment 13.

As shown in fig. 11, the upper surface of the upper plate 1221 is coated with the reflective coating 123 as a reflective object, when the LED lamp 14 located above the lattice of the storage cell 13 emits light obliquely forward and downward, the reflective coating 123 of the upper plate 1221 reflects the light emitted from the LED lamp 14, so that the reflective coating 123 lights up, and the user can determine the location of the storage cell 13 where the light is lit up by seeing the light reflected from the reflective coating 123 of the upper plate 1221, thereby avoiding the situation that the user cannot conveniently see the location of the storage cell where the light is lit up because the handle 122 blocks the storage cell where the user is located. The edge of the front side wall of the tray body 121 is surrounded by a sealing strip 124, when the tray 12 is installed in the inner shell 16, the sealing strip 124 is clamped between the front side of the tray body 121 and the opening of the inner shell 16, and a sealing space is formed between the tray 12 and the inner shell 16 to prevent the food in the tray 12 from contacting with the outside air. Therefore, the shelf life of the food can be prolonged, and the food in different holding trays 12 can be prevented from being tainted with the smell.

In FIG. 1, the food plate storage module 10, the stewpot storage module 20 and the freezer 30 are arranged transversely. Other embodiments could be modified to a vertical intelligent ice chest, as shown in fig. 12, with the food plate storage module 10 and the stewpot storage module 20 in an upright arrangement, with the food plate storage module 10 located above the stewpot storage module 20 and the freezer located on the back side of the bottom of the vertical intelligent ice chest, not shown.

Claims (12)

1. The utility model provides a storage cabinet, is equipped with a plurality of storage check towards the open-ended, is equipped with the detachable drawer in the storage check, drawer open-top, its characterized in that is furnished with detachable roof pad for the interior roof of storage check, and the drawer is packed into then and is enclosed into storage space with the roof pad in the storage check.

2. The storage cabinet of claim 1, including a forwardly opening inner shell removably received in the storage compartment, the drawer being received in the inner shell from the opening of the inner shell, the top wall of the inner shell acting as said top wall pad.

3. The storage cabinet of claim 2, wherein the individual cells are arranged in columns.

4. A storage cabinet according to claim 3, wherein the locking mechanism is common to each cell in a row, in particular, the locking mechanism comprises a vertical rod and a vertical control assembly for controlling the vertical movement of the vertical rod, the vertical rod is provided with a clamping member at a position corresponding to each cell for clamping the inner shells in the corresponding cell, the vertical rod vertically advances to clamp the inner shells loaded into the cells by the clamping member, and the vertical rod vertically resets to unlock the clamping member from clamping the inner shells.

5. The storage case of claim 4, wherein the vertical post is positioned rearward of the interior shell receiving portion of the storage compartment and the retaining member extends toward the interior shell receiving portion.

6. A storage cabinet according to claim 5 wherein a through hole is provided in the rear of each cell in a row, and a vertical post passes through the through hole of each cell.

7. A storage cabinet according to claim 4, wherein the retaining member comprises a catch projecting towards the inner shell, the inner shell being provided with a catch on the bottom or top wall which corresponds to the catch.

8. A storage cabinet according to claim 7, wherein the clip further comprises a carry spring for applying a carry force to the clip, the clip and/or clip being provided with a guide ramp, the upright post being in the carry condition, the clip being biased against the carry force of the carry spring by the inner shell being urged by the guide ramp during loading of the inner shell into the storage compartment and then returning to retain the clip under the carry force of the carry spring.

9. The storage cabinet of claim 4, wherein the vertical control assembly includes a cam mechanism and a spring to provide a locking force to the cam mechanism.

10. The storage case of claim 2, wherein the front end of the bottom wall of the inner case extends downwardly and then rearwardly beyond the retaining tabs, and the retaining tabs cooperate with the bottom wall of the inner case to retain the bottom wall of the storage compartment.

11. The storage cabinet of claim 2, wherein the edge of the drawer front wall is surrounded by a sealing strip to seal a gap between the drawer front wall and the opening of the inner shell.

12. A cabinet according to any one of claims 1 to 11 wherein the cabinet is a smart ice chest for storing food.

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