CN109813041B - Storage device and refrigerator having the same - Google Patents

Abstract

The invention discloses a storage device and a refrigerator with the storage device. The storage device includes a body enclosing an accommodating cavity, a pair of guide mechanisms and a first partition for dividing the accommodating cavity, the body comprising a bottom wall, a pair of first side walls and a pair of second The side wall, the first partition frame is connected to the guide mechanism, and it is characterized in that the guide mechanism includes a plate body and a guide part, and the guide part and the plate body enclose a U-shaped groove with an opening downward , the guide mechanism is hooked on the upper end face of the second side wall through the U-shaped groove, and the guide mechanism can slide back and forth along the upper end face of the second side wall to drive the first partition The rack slides synchronously. The invention can not only improve the degree of freedom and flexibility of dividing the accommodating cavity to meet different storage requirements, but also facilitate assembly/disassembly, which is convenient for users to clean the storage device and choose the guide mechanism and the partition frame as required.

Description

Storage device and refrigerator having the same

technical field

The invention relates to a storage device and a refrigerator with the storage device, belonging to the field of household appliances.

Background technique

Refrigerator storage devices, such as drawers, fresh-keeping boxes, storage boxes, bottle holders, etc., generally have a large accommodating cavity. When placing a variety of foods, the various foods are mixed with each other, which is extremely inconvenient to take and place. In particular, when a variety of foods are intermixed in the freezer drawer, adhesion occurs between the foods after freezing, and it is more inconvenient to take out the food from the freezer drawer of the refrigerator.

In order to solve the above problems, some manufacturers divide the accommodating cavity of the storage device with a partition frame, but often only the accommodating cavity can be simply divided, and the divided space cannot be adjusted freely according to the storage items, and the flexibility is poor; and The assembly structure of the divider is complicated, and it is inconvenient to disassemble and assemble; the storage items in different divided spaces slide and cross each other, and the effect of division cannot be achieved.

SUMMARY OF THE INVENTION

In order to solve at least one of the above problems, the present invention provides a refrigerator and a storage device thereof.

To achieve one of the above objectives, an embodiment of the present invention provides a storage device, the storage device includes a body enclosing a accommodating cavity, a pair of guide mechanisms, and a first partition for dividing the accommodating cavity a frame, the body includes a bottom wall, a pair of first side walls and a pair of second side walls, the first partition frame is connected to the guide mechanism, the guide mechanism includes a plate body and a guide portion, the guide A U-shaped groove with a downward opening is formed between the plate body and the plate body. The upper end of the second side wall slides back and forth to drive the first separator to slide synchronously.

Further, when the guide mechanism is hooked on the upper end surface of the second side wall, the relative movement of the guide mechanism and the second side wall in the left-right direction is restricted; when the first separation When the frame is connected to the guide mechanism, the relative movement of the first partition frame and the guide mechanism in the left-right direction is restricted.

Further, the storage device further includes an adjustment assembly and a second partition frame for dividing the accommodating cavity, the second partition frame is rotatably connected to the first partition through the adjustment assembly around a vertical axis on the shelf.

Further, the second partition rack rotates around the vertical axis relative to the first partition rack to switch the storage device between the stacking state and the unfolding state; when the storage device is in the stacking state When the storage device is in the unfolded state, the partition surface of the second partition shelf is coplanar with the partition surface of the first partition shelf; when the storage device is in the unfolded state, the partition surface of the second partition shelf is in the same plane as the first partition shelf. The partition surfaces of the first partition frame are perpendicular to each other.

Further, the adjustment assembly has a first engagement state corresponding to the stacked state, a second engagement state corresponding to the deployed state, and a position between the first engagement state and the second engagement state. The critical state between the two; when the second dividing frame and the first dividing frame rotate relative to each other, the adjusting assembly is subjected to an elastic driving force, and the elastic driving force drives the adjusting assembly to change from the critical state to the first engagement state or the second engagement state.

Further, the adjustment assembly includes:

a first adjusting mechanism, which is matched with one of the first dividing frame and the second dividing frame;

A second adjusting mechanism is matched with the other one of the first dividing frame and the second dividing frame, and the first adjusting mechanism and the second adjusting mechanism are relatively rotatably connected around the vertical axis , so as to drive the second dividing frame to rotate relative to the first dividing frame.

Further, the adjustment assembly further includes a cam structure, the cam structure includes a first concave-convex curved surface formed on the first adjusting mechanism and a second concave-convex curved surface formed on the second adjusting mechanism; when the When the first adjusting mechanism and the second adjusting mechanism rotate relative to each other around the vertical axis, the second concave-convex curved surface and the first concave-convex curved surface abut and cooperate with each other, so that the first adjusting mechanism and the The second adjusting mechanism performs a reciprocating jumping movement that is relatively far away or relatively close along the vertical direction.

Further, the second divider frame can also be slidably connected to the first divider frame through the adjustment assembly.

Further, the first dividing frame includes a dividing cross bar extending along the left-right direction and used for dividing the accommodating cavity, the second dividing frame includes a dividing vertical rod used for dividing the accommodating cavity; the adjustment assembly includes A first channel and a second channel, the first channel being slidably passed through by one of the dividing cross bar and the dividing longitudinal bar, the second channel being for the dividing cross bar and the dividing longitudinal bar The other of the rods slides through.

To achieve one of the above objectives, an embodiment of the present invention provides a refrigerator including the storage device.

Compared with the prior art, the present invention has the following beneficial effects: by arranging the matching structure of the first partition frame and the guide mechanism, not only the degree of freedom and flexibility of dividing the accommodating cavity can be improved to adapt to different storage requirements, but also the assembly can be improved. /Easy to disassemble, convenient for users to clean the storage device and choose the guide mechanism and divider according to their needs.

Description of drawings

1 is a structural diagram of a storage device according to a first embodiment of the present invention, wherein the storage device is shown in a stacked state;

2 is a structural exploded view of the storage device according to the first embodiment of the present invention;

3 is a structural diagram of the storage device according to the first embodiment of the present invention, wherein the storage device is shown in an unfolded state;

Figure 4a is a structural diagram of the adjusting assembly according to the first embodiment of the present invention when it is in a first engagement state;

Fig. 4b is a structural diagram of the adjusting assembly of the first embodiment of the present invention when it is in a critical state;

Fig. 4c is a structural diagram of the adjusting assembly according to the first embodiment of the present invention when it is in a second engagement state;

5 is an exploded view of the structure of the adjusting assembly according to the first embodiment of the present invention;

Fig. 6a is a structural diagram of the storage device according to the first embodiment of the present invention, wherein the state of the accommodating cavity when zero partition is shown;

Fig. 6b is a structural diagram of the storage device according to the first embodiment of the present invention, which illustrates the state when the accommodating cavity is divided into two partitions;

Fig. 6c is a structural diagram of the storage device according to the first embodiment of the present invention, which illustrates the state when the accommodating cavity is divided into three partitions;

7 is a structural diagram of a storage device according to a second embodiment of the present invention; wherein the storage device is shown in a stacked state;

8 is an exploded view of the structure of the storage device according to the second embodiment of the present invention;

Fig. 9a is a structural diagram of the adjusting assembly according to the second embodiment of the present invention when it is in a first engagement state;

Fig. 9b is a structural diagram of the adjusting assembly of the second embodiment of the present invention when it is in a critical state;

Fig. 9c is a structural diagram of the adjusting assembly according to the second embodiment of the present invention when it is in a second engagement state.

Detailed ways

An embodiment of the present invention provides a refrigerator, the refrigerator includes a box body and a box door, the box body and the box door define at least one storage compartment, and the storage compartment may be a refrigerator compartment, a freezer compartment, Greenhouse etc. The refrigerator further includes a storage device for storing items, the storage device is arranged in the storage compartment, and can be specifically configured as a drawer, a fresh-keeping box, a storage box, a bottle holder, and the like. Hereinafter, the storage device of the present invention will be described in detail with reference to specific embodiments.

Example 1

1 to 6 c , this embodiment provides a storage device 100 , the storage device 100 includes a main body 11 , a pair of guide mechanisms 12 , a first partition frame 132 , a second partition frame 131 and an adjustment assembly 14 .

The main body 11 encloses a substantially rectangular parallelepiped accommodating cavity 10 with an upper opening, and the accommodating cavity 10 is used for storing various kinds of storage items, such as food and beverages. The body 11 includes a bottom wall, a pair of first side walls 11a arranged opposite to each other, and a pair of second side walls 11b arranged opposite to each other. The bottom wall is used to carry storage items, and a pair of first side walls 11a and a pair of second side walls 11b respectively extend vertically upward from the bottom wall.

In order to clearly express the positions and directions described in this embodiment, the direction defined by the relative positions of the pair of first side walls 11a is defined as the front-rear direction (also referred to as the longitudinal direction), and the relative positions of the pair of second side walls 11b The defined direction is defined as the left-right direction (also referred to as the lateral direction). That is, the pair of first side walls 11a are arranged to face each other in the front and rear, and the pair of second side walls 11b are arranged to face each other from left to right. In addition, a plane jointly defined by the front-rear direction and the left-right direction is defined as a horizontal plane, and a direction perpendicular to the horizontal plane is defined as a vertical direction.

1 and 2, a pair of guide mechanisms 12 are respectively provided on a pair of second side walls 11b. The guide mechanism 12 includes a guide rod 12a, a guide member 12b and a fixed seat 12c, wherein: the guide mechanism 12 is fixed on the main body 11 through the fixed seat 12c, and the fixing method between the fixed seat 12c and the main body 11 can be screwed, riveted, clamped The guide rod 12a is parallel to the second side wall 11b and extends forward and backward; the guide member 12b is sleeved on the guide rod 12a and can slide back and forth along the guide rod 12a. When the guide mechanism 12 is fixed to the main body 11, the guide member 12b It can only slide back and forth relative to the main body 11 .

The first partition frame 132 is accommodated in the accommodating cavity 10 and can be used to divide the accommodating cavity 10 back and forth. Specifically, the first partition frame 132 includes a partition member, the partition member is transversely placed in the accommodating cavity 10 for dividing the accommodating cavity 10 , and the vertical plane on which the partition member is located defines the partition of the first partition frame 132 . The accommodating chamber 10 is divided into front and rear with the partition surface of the first partition frame 132 as a boundary. In this embodiment, the partition member includes partition bars 132a and 132b arranged in a long rod shape. The partition bars 132a and 132b extend from left to right and are arranged at intervals in the vertical direction.

The first dividing frame 132 further includes a pair of connecting pieces 132c. The connecting pieces 132c connect the end of the dividing crossbar 132a and the end of the dividing crossbar 132b, and form a rectangular frame with the dividing crossbars 132a and 132b.

The first partition frame 132 is slidably connected to the main body 11 through the guide mechanism 12 , so as to adjust the size and/or quantity of the storage compartments formed by the front and rear divisions of the accommodating cavity 10 . Specifically, the first partition frame 132 includes a pair of fixing parts 132d formed at the left and right ends of the first partition frame 132, and each fixing part 132d is connected to the corresponding guide member 12b. When the guide member 12b slides back and forth along the guide rod 12a, the first partition frame 132 slides back and forth in the accommodating cavity 10 synchronously.

The fixing portion 132d and the guide member 12b are plug-fitted with each other. The fixing portion 132d is specifically arranged in the shape of a long rod, and its extending direction is perpendicular to the extending direction (left-right direction) of the separating bars 132a and 132b; Its extending direction is inserted and fitted into the mounting hole 12d. When the fixing portion 132d is inserted into the mounting hole 12d, the fixing portion 132d and the mounting hole 12d are mutually limited in the left-right direction, so that the fixing portion 132d cannot move left and right relative to the guide member 12b; 132 is limited, so that the first dividing frame 132 cannot move left and right relative to the main body 11, and the stability of the first dividing frame 132 is enhanced.

The outer surface of each guide piece 12b abuts against the corresponding second side wall 11b, so that when the first partition frame 132 tends to move leftward or rightward relative to the main body 11, one of its guide pieces 12b can pass through The resistance against the corresponding second side wall 11b can limit the leftward movement tendency of the first partition frame 132, and the other guide member 12b can restrain the first partition shelf through the resistance against the corresponding second side wall 11b. 132 movement trend to the right.

In the present embodiment, the guide mechanism 12 is disposed outside the body 11 away from the accommodating cavity 10 , and is specifically disposed outside the corresponding second side wall 11 b. The inner side of each guide member 12b is respectively abutted on the corresponding second side wall 11b, thereby enhancing the stability of the guide member 12b during sliding, and preventing the first partition frame 132 from shaking left and right relative to the main body 11 during use.

Each second side wall 11b is provided with a guide groove 11c extending back and forth, and the left and right ends of the first partition frame 132 pass through the guide groove 11c and then are connected to the guide mechanism 12. Specifically, the fixing portion 132d is self-contained 10 passes through the guide groove 11c and then fits into the mounting hole 12d of the guide member 12b.

In this embodiment, the extending direction of the fixing portion 132d is parallel to the extending direction of the guide groove 11c, that is, the fixing portion 132d also extends in the front-rear direction, which not only prevents the first separator 132 from shaking relative to the main body 11 during use Moreover, it is also convenient for the fixing portion 132d to be disassembled from the guide member 12b, thereby facilitating the assembly and disassembly of the first partition frame 132.

Further, the guide member 12b includes a first guide member 121b and a second guide member 122b which are provided separately, and the first guide member 121b and the second guide member 122b are detachably assembled and connected. The installation hole 12d is disposed on the first guide member 121b, the first guide member 121b and the second guide member 122b enclose a channel 12e, and the channel 12e communicates with the installation hole 12d. When the first guide member 121b and the second guide member 122b are separated, the fixing portion 132d may be inserted into the mounting hole 12d from between the first guide member 121b and the second guide member 122b, and then the first guide member 121b and the second guide member 121b The guide member 122b is assembled and connected, so that the second guide member 122b restricts the fixing portion 132d to prevent the fixing portion 132d from being detached from the mounting hole 12d.

Referring to FIGS. 1 to 3 , the second partition frame 131 is accommodated in the accommodating cavity 10 and can be used to divide the accommodating cavity 10 from left to right. In this embodiment, the second divider 131 is rotatably connected to the first divider 132 through the adjusting assembly 14 around the vertical axis t. According to the positional relationship between the second divider 131 and the first divider 132, the storage device 100 has a stacked state (see FIG. 1 ) and an expanded state (see FIG. 3 ). By arranging the second partition rack 131 to be rotatably connected to the first partition rack 132 , the number of storage partitions formed by dividing the accommodating cavity 10 can be adjusted, thereby increasing the flexibility of dividing the accommodating cavity 10 .

The second partition rack 131 includes a partition body that can be used to divide the accommodating cavity 10 , and a vertical plane where the partition body is located defines a partition surface of the second partition rack 131 . The lateral width of the accommodating cavity 10 (that is, the distance between the pair of second side walls 11b ) is greater than the longitudinal width of the accommodating cavity 10 (that is, the spacing between the pair of first side walls 11 a ). The width of the surface is larger than the width of the partition surface of the second partition frame 131 , that is, the length of the partition is longer than the length of the partition.

In this embodiment, the partition body includes long-bar-shaped partition vertical rods 131a and 131b, and the partition vertical rods 131a and 131b are parallel to each other and are arranged at intervals in the vertical direction.

Referring to FIG. 1 , when the storage device 100 is in the stacked state, the partition surface of the second partition shelf 131 and the partition surface of the first partition shelf 132 are coplanar, and the partition vertical bars 131a and 131b and the partition cross bars 132a and 132b are coplanar. Both extend along the left and right directions and are located in the same vertical plane, so that the space occupied by the second partition shelf 131 when not in use can be reduced, and the neatness and aesthetics can be improved at the same time; referring to FIG. 3 , when the storage device 100 is in the unfolded state In the state, the second divider 131 and the first divider 132 are criss-crossed, the accommodating cavity 10 can be divided back and forth with the dividing surface of the first divider 132 as the boundary, and the accommodating cavity 10 can be divided by the second divider 131 The plane is divided into left and right sides. At this time, the dividing surface of the second dividing frame 131 and the dividing surface of the first dividing frame 132 have a non-zero included angle. In this embodiment, the dividing surface of the second dividing frame 131 and The partition surfaces of the first partition frame 132 are perpendicular to each other. Specifically, the partition vertical rods 131a and 131b extend in the front-rear direction, the partition horizontal rods 132a and 132b extend in the left-right direction, and the partition vertical rods 131a and 131b are perpendicular to the partition horizontal rods 132a and 132b. .

Further, the partition member further includes a glass partition plate 133a, and the partition plate 133a can be selectively assembled between the partition rail 132a and the partition rail 132b by the user through the first fixing member 133b and the second fixing member 133e. Wherein, the partition plate 133a is assembled to the connecting member 132c through the first fixing member 133b, and is detachably connected to the adjusting assembly 14 through the second fixing member 133e. By arranging the partitions 133a, the stored items in the storage areas on the front and rear sides of the first partition shelf 132 are not in contact, so as to avoid smell and prevent the stored items from sliding down between the partition bars 132a and 132b. Of course, in alternative embodiments, the partition 133a may not only be located between the dividing rail 132a and the dividing rail 132b, but may also extend partially upward and above the dividing rail 132a, and/or partially extending downward to the dividing rail 132b below.

In the vertical direction, the separation vertical rod 131a and the separation vertical rod 131b are arranged adjacent to each other, and the separation vertical rod 131a is always higher than the upper boundary of the separator (in this embodiment, the separation horizontal rod 132a), and the separation vertical rod 131a The bar 131b is always below the lower boundary of the divider (in this embodiment also the divider cross bar 132b). The dividing vertical rods 131a, the dividing horizontal rods 132a, the partition plates 133a, the dividing horizontal rods 132b, and the dividing vertical rods 131b are arranged in order in the vertical direction. In this way, when the storage device 100 is in the stacked state, the second partition shelf 131 will not interfere with the partition plate 133a.

Further, the second divider 131 can also be slidably connected to the first divider 132 through the adjustment assembly 14, that is, the second divider 131 can both slide and rotate relative to the first divider 132 around the vertical axis t , so as to adjust the number/size of the storage partitions formed by dividing the accommodating cavity 10 as required.

Wherein, the above-mentioned second divider 131 is slidably connected to the first divider 132 through the adjustment assembly 14, and there are multiple implementations: first, the first divider 132 is non-slidably connected to the adjustment assembly 14, and the second divider The rack 131 is slidably connected to the adjustment assembly 14, so that the size/number of the storage compartments formed by the front and rear divisions of the accommodating chamber 10 by the first partition rack 132 can be adjusted; secondly, the first partition rack 132 is slidably connected to the adjustment assembly 14, The two partitions 131 are non-slidably connected to the adjustment assembly 14, so that the size/number of the storage compartments formed by the left and right divisions of the accommodating cavity 10 by the second partitions 131 can be adjusted; thirdly, in this embodiment, the first partitions 132 It is slidably connected to the adjustment assembly 14, and the second divider 131 is also slidably connected to the adjustment assembly 14, so that the storage compartment 10 is formed by the front and rear divisions of the first divider 132 and the left and right divisions formed by the second divider 131. The size/number of storage partitions can be adjusted for greater flexibility.

4a-5, the specific structure of the adjustment assembly 14 will be described in detail. In this embodiment, the adjustment assembly 14 is configured as a cylindrical structure with mirror symmetry along a horizontal plane q. Of course, in the modified embodiment, its shape and structure are not limited to this embodiment.

The adjustment assembly 14 includes a first adjustment mechanism and a second adjustment mechanism. The first adjusting mechanism is matched with one of the first dividing frame 132 and the second dividing frame 131 , and the second adjusting mechanism is matched with the other one of the first dividing frame 132 and the second dividing frame 131 . In this embodiment, the first adjustment mechanism is matched with the first partition frame 132 and is provided in two, that is, the first adjustment mechanism 142a matched with the partition rail 132a and the first adjustment mechanism 142a matched with the partition rail 132b There are two first adjustment mechanisms 142b; the second adjustment mechanism is matched with the second partition frame 131, and there are also two, that is, the second adjustment mechanism 141a matched with the partition vertical rod 131a and the second adjustment mechanism 141a matched with the partition vertical rod 131b. The connected second adjustment mechanism 141b; the first adjustment mechanism 142a matches the second adjustment mechanism 141a, and the first adjustment mechanism 142b matches the second adjustment mechanism 141b.

The first adjustment mechanism 142a includes a third member 43a, a fourth member 44a, and a first channel 145a. Wherein, the third member 43a includes two hooks 434a and a groove 433a; the fourth member 44a includes two hooks 441a and a groove 442a; the two hooks 434a correspond to the two slots 441a one-to-one and snap fit connected, so that the third member 43a and the fourth member 44a are assembled and assembled with each other; the first channel 145a is formed between the third member 43a and the fourth member 44a, which is specifically enclosed by the groove 433a and the groove 442a together, Therefore, the assembly and connection of the first adjusting mechanism 142a and the separating cross bar 132a are facilitated. The first passage 145a is passed through by the dividing rail 132a, so that the first adjusting mechanism 142a slides along the dividing rail 132a.

Similarly, the first adjusting mechanism 142b is assembled and assembled with the separating cross bar 132b, and its specific structure can be referred to the first adjusting mechanism 142a, which will not be repeated here. The first channel 145a and the first channel 145b are parallel, and the adjusting assembly 14 is slidably fitted to the first partition frame 132 from left to right.

The second adjustment mechanism 141a includes a first member 41a, a second member 42a, and a second channel 144a. Wherein, the first member 41a includes two hooks 411a and a groove 412a; the second member 42a includes two hooks 421a and a groove 422a; the two hooks 411a correspond to the two slots 421a one-to-one and snap fit The second channel 144a is formed between the first member 41a and the second member 42a, which is specifically enclosed by the groove 422a and the groove 412a together, Therefore, the assembly and connection of the second adjusting mechanism 141a and the separating longitudinal rod 131a are facilitated. The second passage 144a allows the dividing longitudinal rod 131a to pass through, so that the second adjusting mechanism 141a slides along the dividing longitudinal rod 131a.

Similarly, the second adjusting mechanism 141b is assembled and assembled with the separating longitudinal rod 131b, and the specific structure thereof can be referred to the second adjusting mechanism 141a, which will not be repeated here. The second channel 141 a and the second channel 141 b are parallel, and the adjusting assembly 14 is slidably fitted to the second partition frame 131 .

Further, the first adjustment mechanism 142a includes a matching column 432a, and the second adjustment mechanism 141a includes a matching hole matching the matching column 432a; the matching column 432a and the matching hole of the second adjustment mechanism 141a can be aligned along the They are plug-fitted in the vertical direction, and the two have cylindrical mating surfaces that match each other, so that the first adjusting mechanism 142a and the second adjusting mechanism 141a are matched and can be rotated relative to each other around the vertical axis t. In the embodiment, (taking the main body 11 as a reference) the second adjusting mechanism 141a rotates around the vertical axis t. Similarly, the second adjustment mechanism 141b includes a matching hole 424b, and the first adjustment mechanism 142b includes a matching column matching the matching hole 424b; the matching hole 424b and the matching column of the first adjustment mechanism 142b can be aligned along the They are plug-fitted in the vertical direction, and the two have cylindrical mating surfaces that match each other, so that the first adjusting mechanism 142b and the second adjusting mechanism 141b are matched and can be rotated relative to each other around the vertical axis t. In the embodiment, (with the main body 11 as a reference) the second adjusting mechanism 141b rotates around the vertical axis t.

In addition, when the matching post 432a and the matching hole of the second adjusting mechanism 141a are mated, the two are limited to each other, so that the relative displacement in the horizontal direction of the first adjusting mechanism 142a and the second adjusting mechanism 141a is limited, to avoid shaking. Likewise, when the fitting hole 424b and the fitting post of the first adjusting mechanism 142b are mutually limited, the relative displacement in the horizontal direction of the first adjusting mechanism 142b and the second adjusting mechanism 141b is limited, thereby avoiding shaking.

In this way, through the relative rotation of the first adjusting mechanisms 142a, 142b and the second adjusting mechanisms 141a, 141b, the first dividing frame 132 and the second dividing frame 131 are driven to rotate relative to each other around the vertical axis t, so that the storage device 100 is placed in the switching between the stacked state and the unfolded state.

Specifically, the adjustment assembly 14 further includes a cam structure formed between the first adjustment mechanism and the second adjustment mechanism. In this embodiment, the number of the cam structures is set to two, that is, the cam structure 143a formed between the first adjusting mechanism 142a and the second adjusting mechanism 141a, and the cam structure 143a formed between the first adjusting mechanism 142b and the second adjusting mechanism 141a The cam structure 143b between the adjustment mechanisms 141b. Of course, in a modified embodiment, only one of the cam structure 143a and the cam structure 143b may be provided.

Taking the cam structure 143a as an example, the specific structure of the cam structure will be introduced (for the specific structure of the cam structure 143b, refer to the cam structure 143a, which will not be repeated). The cam structure 143a includes a first concave-convex curved surface 431a formed on the upper end surface of the first adjusting mechanism 142a and a second concave-convex curved surface 423a formed on the lower end surface of the second adjusting mechanism 141a. When the first adjusting mechanism 142a and the second adjusting mechanism 141a rotate relative to each other around the vertical axis t, the second concave-convex curved surface 423a and the first concave-convex curved surface 431a abut against each other, In order to make the first adjustment mechanism 142a and the second adjustment mechanism 141a perform a reciprocating jumping motion away from or close to each other in the vertical direction.

The cam structure 143a has at least two lowest point engagement positions where the second concave-convex curved surface 423a and the first concave-convex curved surface 431a are concave-convex matched with each other (see FIGS. 4a and 4c ), and the second concave-convex curved surface 423a and the first concave-convex curved surface 431a are in convex-concave contact with each other The highest point of the contact abutting position (see Figure 4b). When the cam structure 143a moves from the lowest point engaging position to the highest point abutting position, the first adjusting mechanism 142a and the second adjusting mechanism 141a move away from each other in the vertical direction; when the cam structure 143a moves from the highest point When the abutting position moves to the lowest point engaging position, the first adjusting mechanism 142a and the second adjusting mechanism 141a approach each other in a vertical direction relative to each other.

When the second divider 131 rotates relative to the first divider 132 around the vertical axis t, in the process that the shelf assembly 100 changes from the stacked state to the expanded state (the shelf assembly 100 changes from the expanded state) The process to the superimposed state is the opposite, and will not be repeated) as an example:

4a, when the storage device 100 is in the stacked state, the adjustment assembly 14 is in the first engagement state, at this time, the first channels 145a, 145b and the second channels 144a, 144b are parallel, correspondingly, the first The dividing surface of the dividing frame 132 is parallel to the dividing surface of the second dividing frame 131, and the cam structures 143a and 143b are both in the lowest engagement position;

Referring to FIG. 4b, when the storage device 100 is switched from the stacked state to the unfolded state, in the process of changing the adjustment assembly 14 from the first engagement state to the critical state, the cam structures 143a, 143b are both changed from one of the lowest The point engaging position moves to the highest point abutting position, the first adjustment mechanism 142a and the second adjustment mechanism 141a are vertically away from each other, and the first adjustment mechanism 142b and the second adjustment mechanism 141b are away from each other in the vertical direction; until The adjusting assembly 14 is in a critical state, and the cam structures 143a and 143b are both in the highest abutting position; then, during the process of changing the adjusting assembly 14 from the critical state to the second meshing state, the first adjusting mechanism 142a and the second adjusting mechanism 141a are close to each other in the vertical direction, and the first adjusting mechanism 142b and the second adjusting mechanism 141b are close to each other in the vertical direction;

4c, when the storage device 100 is in the unfolded state, the adjustment assembly 14 is in the second engagement state, at this time, the first channels 145a, 145b and the second channels 144a, 144b are perpendicular, correspondingly, the first separation The partition surface of the shelf 132 is perpendicular to the partition surface of the second partition shelf 131 , and the cam structures 143 a and 143 b are both at the other lowest point engaging positions.

Further, the cam structures 143a and 143b are both configured as four-circle bisected structures, that is, when the cam structures 143a and 143b are changed between the two adjacent lowermost meshing positions, the first adjustment mechanism 142a and the second adjustment mechanism The mechanism 141a rotates 90° relative to the vertical axis t, and the first adjustment mechanism 142b and the second adjustment mechanism 141b rotate 90° relative to the vertical axis t. Furthermore, the second partition shelf 131 rotates 90° relative to the first partition shelf 132 around the vertical axis t, so that the storage device 100 is switched between the stacked state and the unfolded state, completing a turning cycle.

At the same time, when the cam structures 143a and 143b change between the lowest point engaging position and the highest point abutting position, the first adjustment mechanism 142a and the second adjustment mechanism 141a rotate 45° relative to each other around the vertical axis t, and the first adjustment mechanism The mechanism 142b rotates 45° relative to the second adjustment mechanism 141b around the vertical axis t.

Further, when the cam structures 143a, 143b are not in the lowest point engagement position, the adjusting assembly 14 is always subjected to an elastic driving force that drives the cam structures 143a, 143b to move to the lowest point engagement position, that is, the elastic force The driving force drives the first adjustment mechanism 142a and the second adjustment mechanism 141a to have a tendency to approach each other in the vertical direction and the first adjustment mechanism 142b and the second adjustment mechanism 141b to have a tendency to approach each other in the vertical direction.

In this embodiment, the elastic driving force is provided by the second partition frame 131 . Specifically, the second dividing frame 131 is made of a rigid material, and further includes a pair of connecting rods 131c connecting the end of the dividing longitudinal rod 131a and the end of the dividing longitudinal rod 131b; the fourth member 44a and the fourth member 44b are integrally formed , the fourth member 44a is arranged as the upper half of the structural member 44, and the fourth member 44b is arranged as the lower half of the member 44, so that the first adjustment mechanisms 142a and 142b are fixedly connected in the vertical direction. When the cam structures 143a, 143b are in the lowest engagement position, the second spacer 131 does not have elastic deformation, and the split longitudinal rods 131a, 131b are parallel to each other and have an initial distance; when the cam structures 143a, 143b are not in the lowest point In the point engagement position (including between the lowest point engagement position and the highest point abutting position and at the highest point abutting position), driven by the second adjustment mechanisms 141a and 141b, the longitudinal rod 131a is divided. The partial distance of 131b near the adjustment component 14 is greater than the initial distance, and the end is maintained at the initial distance under the pulling of the connecting rod 131c, and then the second divider 131 is elastically deformed, and the elastically deformed second divider 131 applies the elastic driving force on the adjustment assembly 14 .

In this way, in a flip cycle of the storage device 100 being switched between the stacked state and the unfolded state: under the action of an artificial external force, the second divider 131 rotates relative to the first divider 132 around the vertical axis t, and adjusts the The assembly 14 changes from the first engagement state to the critical state (or from the second engagement state to the critical state), the cam structures 143a and 143b move from the lowest engagement position to the highest abutment position, and the second adjustment The mechanisms 141a, 141b move away from each other in the vertical direction, and drive the second partition frame 131 to elastically deform; when the adjustment assembly 14 reaches the critical state, the cam structures 143a, 143b are both in the highest abutting position, and the second partition frame 131 The elastic deformation reaches the maximum; beyond the critical state, under the action of the elastic restoring force of the second partition frame 131, the second adjusting mechanisms 141a, 141b approach each other in the vertical direction, and the adjusting assembly 14 changes from the critical state to the second meshing state ( or from the critical state to the first engagement state), so that the storage device 100 is transformed from the stacked state to the unfolded state (or from the unfolded state to the stacked state).

Of course, in a modified embodiment, the storage device 100 may further include an elastic member for providing the elastic driving force, and the elastic member is disposed between the first adjustment mechanism and the second adjustment mechanism. When the cam structure is not in the engagement position of the lowest point, the elastic member is elastically deformed.

Further, the connecting rods 131c are arranged to be non-coplanar with the dividing longitudinal rods 131a and 131b, and when the storage device 100 is in the superimposed state, a pair of connecting rods 131c abuts against the dividing cross rods 132a and 132b and respectively It is located on the front and rear sides of the first partition frame 132 .

Compared with the prior art, in the storage device 100 of the present embodiment, the number/size of the storage partitions formed by dividing the accommodating cavity 10 can be adjusted as required, for example, through the Movement to form zero partition as shown in FIG. 6a, two partitions as shown in FIG. 6b or FIG. 1, and four partitions as shown in FIG. 3, or by disassembling and replacing the second partition 131 to form three partitions as shown in FIG. 6c; and the first partition 132 It is convenient to disassemble and assemble, and has good stability during use; the storage partitions formed by the division of the first partition frame 132 can avoid cross-dropping.

Example 2

Referring to FIGS. 7 to 9 c , the present embodiment provides a storage device 200 . The storage device 200 includes a main body 21 , a pair of guide mechanisms 22 , a first partition frame 232 , a second partition frame 231 and an adjustment assembly 24 .

The main body 21 encloses a substantially rectangular parallelepiped accommodating cavity 20 with an upper opening, and the accommodating cavity 20 is used to store various storage items, such as food and beverages. The body 21 specifically includes a bottom wall, a pair of first side walls 21a arranged opposite to each other, and a pair of second side walls 21b arranged opposite to each other. The bottom wall is used to carry storage items, and a pair of first side walls 21a and a pair of second side walls 21b respectively extend vertically upward from the bottom wall.

In order to clearly express the positions and directions described in this embodiment, the direction defined by the relative positions of the pair of first side walls 21a is defined as the front-rear direction (also referred to as the longitudinal direction), and the relative positions of the pair of second side walls 21b The defined direction is defined as the left-right direction (also referred to as the lateral direction). That is, the pair of first side walls 21a are arranged to face each other in front and rear, and the pair of second side walls 21b are arranged opposite to left and right. In addition, a plane jointly defined by the front-rear direction and the left-right direction is defined as a horizontal plane, and a direction perpendicular to the horizontal plane is defined as a vertical direction.

The pair of guide mechanisms 22 are respectively disposed on the pair of second side walls 21b, that is, each second side wall 21b is provided with a guide mechanism 22. The guide mechanism 22 specifically includes a plate body 22a, a guide portion 22b, and a mounting hole 22c. The guide portion 22b and the plate body 22a enclose a U-shaped groove with a downward opening, and the guide mechanism 22 is hooked to the upper end surface of the second side wall 21b through the U-shaped groove, and the guide mechanism 22 can move along the second side wall 21b. The upper end of the side wall 21b slides back and forth, so that the guide mechanism 22 and the first partition frame 232 can be easily disassembled or assembled from the accommodating cavity 10 . Moreover, when the guide mechanism 22 is hooked on the upper end surface of the second side wall 21b, the relative movement of the guide mechanism 22 and the second side wall 21b in the left-right direction is restricted.

The first partition frame 232 is accommodated in the accommodating cavity 20 and can be used to divide the accommodating cavity 20 back and forth. Specifically, the first partition frame 232 includes a partition member, the partition member is transversely disposed in the accommodating cavity 20 for dividing the accommodating cavity 20 , and the vertical plane on which the partition member is located defines the partition of the first partition frame 232 . The accommodating chamber 20 is divided into front and rear with the partition surface of the first partition frame 232 as a boundary. In the present embodiment, the partition member includes partition bars 232a, 232b arranged in the shape of long rods, and the separator bars 232a, 232b extend left and right and are arranged at intervals in the vertical direction.

The first partition frame 232 is slidably connected to the main body 21 in the front-rear direction through the guide mechanism 22. Through the sliding of the first partition frame 232, the size and/or number of the storage partitions formed by the front and rear divisions of the accommodating cavity 20 can be adjusted to suit the Diversified needs for different storage items.

Specifically, the first dividing frame 232 includes fixing portions 232d formed at the left and right ends of the first dividing frame 232 . The fixing portions 232d are fitted into the mounting holes 22c of the guide mechanism 22 , so that the first dividing frame 232 can pass through the guide mechanism 22 . It is slidably arranged in the accommodating cavity 20 back and forth. That is, when the guide mechanism 22 slides back and forth, the first partition frame 232 slides in the accommodating cavity 20 synchronously.

The fixing portion 232d extends along the left-right direction, and can be inserted into the mounting hole 22c along the left-right direction. When the fixing portion 232d is inserted into the mounting hole 22c and the guide mechanism 22 is hooked on the second side wall 21b, the guide mechanism 22 cannot move left and right relative to the main body 21, and the fixing portion 232d and the mounting hole 22c are mutually limited in the left-right direction. , so that the first dividing frame 232 cannot move left and right relative to the guide mechanism 22 , and the first dividing frame 232 cannot move left and right relative to the main body 21 , thereby enhancing the stability of the first dividing frame 232 .

The second partition frame 231 is accommodated in the accommodating cavity 20 and can be used to divide the accommodating cavity 20 from left to right. In this embodiment, the second divider 231 is rotatably connected to the first divider 232 through the adjustment assembly 24 around the vertical axis t1. According to the positional relationship between the second divider 231 and the first divider 232, the storage device 200 has a stacked state (see Figure 7) and an expanded state. In this way, the number of storage partitions formed by dividing the accommodating cavity 20 can be adjusted as required, thereby increasing the flexibility of dividing the accommodating cavity 20 .

The second partition rack 231 includes a partition body that can be used to divide the accommodating cavity 20 , and a vertical plane where the partition body is located defines a partition surface of the second partition rack 231 . The lateral width of the accommodating cavity 20 (ie the distance between the pair of second side walls 21b) is greater than the longitudinal width of the accommodating cavity 20 (ie the distance between the pair of first side walls 21a). The width of the surface is larger than the width of the partition surface of the second partition frame 231 , that is, the length of the partition is larger than the length of the partition.

In this embodiment, the partition body includes long-bar-shaped partition longitudinal rods 231a and 231b, and the partition longitudinal rods 231a and 231b are parallel to each other and arranged at intervals in the vertical direction.

7 , when the storage device 200 is in the stacked state, the partition surface of the second partition shelf 231 and the partition surface of the first partition shelf 232 are coplanar, the partition vertical bars 231a, 231b and the partition cross bars 232a, 232b They all extend in the left-right direction and are located in the same vertical plane, and the separating horizontal bars 232a, the separating vertical bars 231a, the separating vertical bars 231b, and the separating horizontal bars 232b are arranged in sequence in the vertical direction; when the storage device 200 is in the unfolded state In the state, the second divider 231 and the first divider 232 are arranged crosswise, the accommodating cavity 20 can be divided back and forth with the dividing surface of the first divider 232 as the boundary, and the accommodating cavity 20 can be divided by the second divider 231 The plane is divided into left and right. At this time, the dividing surface of the second dividing frame 231 and the dividing surface of the first dividing frame 232 have a non-zero included angle. In this embodiment, the dividing surface of the second dividing frame 231 and The partition surfaces of the first partition frame 232 are perpendicular to each other. Specifically, the partition vertical rods 231a and 231b extend in the front-rear direction, the partition horizontal rods 232a and 232b extend in the left-right direction, and the partition vertical rods 231a and 231b are perpendicular to the partition horizontal rods 232a and 232b. .

The second divider 231 also includes a pair of connecting rods 231c. The connecting rod 231c connects the end of the dividing longitudinal rod 231a and the end of the dividing longitudinal rod 231b.

Further, the second divider 231 can also be slidably connected to the first divider 232 through the adjusting assembly 24 , that is, the second divider 231 can both slide and rotate relative to the first divider 232 around the vertical axis t1 , so as to adjust the number/size of the storage partitions formed by dividing the accommodating cavity 20 .

Wherein, the above-mentioned second divider 231 is slidably connected to the first divider 232 through the adjustment assembly 24, and there are multiple implementations: first, the first divider 232 is non-slidably connected to the adjustment assembly 24, and the second divider The rack 231 is slidably connected to the adjustment assembly 24, so that the size/number of the storage compartments formed by the front and rear divisions of the accommodating cavity 20 by the first partition rack 232 can be adjusted; secondly, the first partition rack 232 is slidably connected to the adjustment assembly 24, The two partitions 231 are non-slidably connected to the adjustment assembly 24, so that the size/number of the storage compartments formed by the left and right divisions of the accommodating cavity 20 by the second partitions 231 can be adjusted; thirdly, as in this embodiment, the first partitions 232 It is slidably connected to the adjustment assembly 24, and the second partition frame 231 is also slidably connected to the adjustment assembly 24, so that the storage area formed by the front and rear divisions of the accommodating cavity 20 by the first partition frame 232 and the left and right partitions formed by the second partition frame 231 are formed. The size/number of storage partitions can be adjusted for greater flexibility.

The specific structure of the adjusting assembly 24 in this embodiment is the same as the specific structure of the adjusting assembly 14 in Embodiment 1, and will not be repeated here. The connection relationship is described in detail below.

The adjustment assembly 24 is arranged as a cylindrical structure with mirror symmetry along a horizontal plane q'.

The adjusting assembly 24 includes a second adjusting mechanism matched with the first dividing frame 232 and a first adjusting mechanism matched with the second dividing frame 231 . In this embodiment, there are two second adjustment mechanisms, that is, the second adjustment mechanism 241a (for its specific structure, please refer to the second adjustment mechanism 141a in Embodiment 1) which is matched with the separating crossbar 232a, and the second adjustment mechanism 241a which is matched with the separating crossbar 232a and the The second adjusting mechanism 241b matched with the horizontal bar 232b (for its specific structure, please refer to the second adjusting mechanism 141b in Embodiment 1); the number of the first adjusting mechanisms is also set to two, that is, the second adjusting mechanism matched with the separating vertical bar 231a. An adjustment mechanism 242a (refer to the first adjustment mechanism 142a of Embodiment 1 for its specific structure) and a first adjustment mechanism 242b (refer to the first adjustment mechanism 142b of Embodiment 1 for its specific structure) matched with the separating longitudinal rod 231b; An adjustment mechanism 242a is matched with the second adjustment mechanism 241a, and the first adjustment mechanism 242b is matched with the second adjustment mechanism 241b.

The first adjusting mechanism 242a includes a first channel 245a for the dividing longitudinal rod 231a to pass through. When the first adjusting mechanism 242a is assembled with the dividing longitudinal rod 231a, the first adjusting mechanism 242a slides along the dividing longitudinal rod 231a; the same The first adjusting mechanism 242b includes a first channel 245b through which the dividing longitudinal rod 231b passes. When the first adjusting mechanism 242b is assembled with the dividing longitudinal rod 231b, the first adjusting mechanism 242b slides along the dividing longitudinal rod 231b. The first channel 245a and the first channel 245b are parallel, and the adjusting assembly 24 is slidably coupled to the second partition frame 231 .

The second adjusting mechanism 241a includes a second passage 244a through which the dividing cross bar 232a passes. When the second adjusting mechanism 241a is assembled with the dividing cross bar 232a, the second adjusting mechanism 241a slides along the dividing cross bar 232a; the same , the second adjusting mechanism 241b includes a second channel 244b for the separating cross bar 232b to pass through. When the second adjusting mechanism 241b is assembled with the separating cross bar 232b, the second adjusting mechanism 241b slides along the separating cross bar 232b. The second channel 241a and the second channel 241b are parallel, and the adjusting assembly 24 is slidably fitted to the first partition frame 232 from left to right.

Further, the first adjustment mechanism 242a and the second adjustment mechanism 241a are matched and can rotate relative to each other around the vertical axis t1. In this embodiment, (with the body 21 as a reference) the first adjustment mechanism 242a is around the vertical axis t1 turn. Similarly, the first adjustment mechanism 242b and the second adjustment mechanism 241b are matched and can rotate relative to each other around the vertical axis t1. In this embodiment, (with the body 21 as a reference) the first adjustment mechanism 242b is around the vertical axis t1 turn.

Specifically, the adjustment assembly 24 further includes a cam structure formed between the first adjustment mechanism and the second adjustment mechanism. In this embodiment, the number of the cam structures is set to two, that is, the cam structure 243a formed between the first adjusting mechanism 242a and the second adjusting mechanism 241a, and the cam structure 243a formed between the first adjusting mechanism 242b and the second adjusting mechanism 241a The cam structure 243b between the adjustment mechanisms 241b. Of course, in a modified embodiment, only one of the cam structure 243a and the cam structure 243b may be provided.

Taking the cam structure 243a as an example, the specific structure of the cam structure will be introduced (for the specific structure of the cam structure 243b, refer to the cam structure 243a, which will not be repeated). The cam structure 243a includes a first concave-convex curved surface 431a' formed on the upper end surface of the first adjusting mechanism 242a and a second concave-convex curved surface 423a' formed on the lower end surface of the second adjusting mechanism 241a. The concave-convex curved surface 431a' and the second concave-convex curved surface 423a' are matched; and when the first adjusting mechanism 242a and the second adjusting mechanism 241a rotate relative to each other around the vertical axis t1, the second concave-convex curved surface 423a' and the first concave-convex curved surface 431a 'Abut each other and cooperate with each other, so that the first adjusting mechanism 242a and the second adjusting mechanism 241a make a reciprocating jumping movement away from or close to each other in the vertical direction.

The cam structure 243a has at least two lowest point engagement positions where the second concave-convex curved surface 423a' and the first concave-convex curved surface 431a' are concave-convex matched with each other (see Figs. The highest point abutting position (refer to FIG. 9b ) where the convex and concave contact with each other. When the cam structure 243a moves from the lowest point engaging position to the highest point abutting position, the first adjusting mechanism 242a and the second adjusting mechanism 241a move away from each other in the vertical direction; when the cam structure 243a moves from the highest point When the abutting position moves to the lowest point engaging position, the first adjusting mechanism 242a and the second adjusting mechanism 241a approach each other in a vertical direction relative to each other.

When the second divider 231 rotates relative to the first divider 232 around the vertical axis t1, in the process that the shelf assembly 200 changes from the stacked state to the expanded state (the shelf assembly 200 changes from the expanded state) The process to the superimposed state is the opposite, and will not be repeated) as an example:

9a, when the storage device 200 is in the stacked state, the adjustment assembly 24 is in the first engagement state, at this time, the first channels 245a, 245b and the second channels 244a, 244b are parallel, correspondingly, the first The partition surface of the partition frame 232 is parallel to the partition surface of the second partition frame 231, and the cam structures 243a and 243b are both in the lowest engagement position;

Referring to FIG. 9b, when the storage device 200 is switched from the stacked state to the unfolded state, in the process of changing the adjustment assembly 24 from the first engagement state to the critical state, the cam structures 243a, 243b are both changed from one of the lowest The point engaging position moves to the highest point abutting position, the first adjustment mechanism 242a and the second adjustment mechanism 241a are vertically away from each other, and the first adjustment mechanism 242b and the second adjustment mechanism 241b are away from each other in the vertical direction; until The adjusting assembly 24 is in a critical state, and the cam structures 243a and 243b are both in the highest abutting position; then, during the process of changing the adjusting assembly 24 from the critical state to the second engaging state, the first adjusting mechanism 242a and the second adjusting mechanism 241a are close to each other in the vertical direction, and the first adjusting mechanism 242b and the second adjusting mechanism 241b are close to each other in the vertical direction;

9c, when the storage device 200 is in the unfolded state, the adjustment assembly 24 is in the second engagement state, at this time, the first channels 245a, 245b and the second channels 244a, 244b are perpendicular, correspondingly, the first separation The separation surface of the frame 232 is perpendicular to the separation surface of the second separation frame 231 , and the cam structures 243 a and 243 b are both at the other lowest point engaging positions.

Further, the cam structures 243a and 243b are both configured as four-circle bisected structures, that is, when the cam structures 243a and 243b change between the adjacent two adjacent lowest point engagement positions, the first adjustment mechanism 242a and the second adjustment mechanism The mechanism 241a rotates 90° relative to the vertical axis t1, and the first adjustment mechanism 242b and the second adjustment mechanism 241b rotate 90° relative to the vertical axis t1. Furthermore, the second partition frame 231 rotates 90° relative to the first partition frame 232 around the vertical axis t1 , so that the storage device 200 is switched between the stacked state and the unfolded state to complete a turning cycle.

At the same time, when the cam structures 243a and 243b change between the lowest point engaging position and the highest point abutting position, the first adjustment mechanism 242a and the second adjustment mechanism 241a rotate 45° relative to each other around the vertical axis t1, and the first adjustment mechanism The mechanism 242b rotates 45° relative to the second adjustment mechanism 241b around the vertical axis t1.

Further, when the cam structures 243a, 243b are not in the lowest point engaging position, the adjusting assembly 24 is always subjected to an elastic driving force that drives the cam structures 243a, 243b to move to the lowest point engaging position, that is, the elastic force The driving force drives the first adjustment mechanism 242a and the second adjustment mechanism 241a to have a tendency to approach each other in the vertical direction and the first adjustment mechanism 242b and the second adjustment mechanism 241b to have a tendency to approach each other in the vertical direction.

In this embodiment, the elastic driving force is provided by the first partition frame 232 . Specifically, the first partition frame 232 is made of a rigid material, and further includes a pair of connecting pieces 232c connecting the ends of the separating cross bars 232a and the ends of the separating cross bars 232b. The connecting pieces 232c are common with the separating cross bars 232a and 232b. A rectangular frame is formed; the first adjusting mechanisms 242a and 242b are fixedly connected in the vertical direction. When the cam structures 243a, 243b are in the lowest engagement position, the first partition frame 232 does not have elastic deformation, and the partition bars 232a, 232b are parallel to each other and have an initial distance; when the cam structures 243a, 243b are not in the lowest point In the point engagement position (including between the lowest point engagement position and the highest point abutting position and at the highest point abutting position), driven by the second adjusting mechanisms 241a, 241b, the separating cross bar 232a The partial distance of 232b near the adjustment component 24 is greater than the initial distance, and the end is maintained at the initial distance under the pulling of the connecting piece 232c, and then the first partition frame 232 has elastic deformation, and the elastically deformed first partition frame 232 applies the elastic driving force on the adjustment assembly 24 .

In this way, in a flip cycle of the storage device 200 being switched between the stacked state and the unfolded state: under the action of an artificial external force, the second divider 231 rotates relative to the first divider 232 around the vertical axis t1 to adjust the The assembly 24 changes from the first engagement state to the critical state (or from the second engagement state to the critical state), the cam structures 243a, 243b both move from the lowest engagement position to the highest abutment position, and the second adjustment The mechanisms 241a, 241b move away from each other in the vertical direction, and drive the first partition frame 232 to elastically deform; when the adjustment assembly 24 reaches the critical state, the cam structures 243a, 243b are both in the highest abutting position, and the first partition frame 232 The elastic deformation reaches the maximum; beyond the critical state, under the action of the elastic restoring force of the first separator 232, the second adjusting mechanisms 241a, 241b approach each other in the vertical direction, and the adjusting assembly 24 changes from the critical state to the second meshing state ( or from the critical state to the first engagement state), so that the storage device 200 is transformed from the stacked state to the unfolded state (or from the unfolded state to the stacked state).

Of course, in a modified embodiment, the storage device 200 may further include an elastic member for providing the elastic driving force, and the elastic member is disposed between the first adjustment mechanism and the second adjustment mechanism. When the cam structure is not in the engagement position of the lowest point, the elastic member is elastically deformed.

Compared with the prior art, the storage device 200 of the present embodiment can adjust the number/size of the storage partitions formed by dividing the accommodating cavity 20 as needed; and the disassembly and assembly of the first partition frame 232 is convenient and stable during use. good sex.

Of course, in a modified embodiment, the first adjustment mechanism can be set as one, and the upper and lower ends of the first adjustment mechanism can be connected with one of the second adjustment mechanisms respectively; or, two of the second adjustment mechanisms can be arranged vertically The directions are fixedly connected, the two first adjustment mechanisms are arranged separately, and when the adjustment assembly changes from the first engagement state to the critical state, the two first adjustment mechanisms move relatively close to each other in the vertical direction. None of these changes depart from the technical spirit of the present invention.

Although this specification is described according to the embodiments, not every embodiment only includes an independent technical solution. Those skilled in the art should take the description as a whole, and the technical solutions in each embodiment can also be appropriately combined to form an independent technical solution in the art. Other embodiments will be understood by the skilled person.

Claims (7)

1. A storage device comprises a body enclosing a containing cavity, an adjusting assembly, a pair of guide mechanisms, a first separating frame and a second separating frame, wherein the first separating frame and the second separating frame are used for separating the containing cavity, the body comprises a bottom wall, a pair of first side walls opposite to each other in the front-back direction and a pair of second side walls opposite to each other in the left-right direction, the first separating frame is connected to the guide mechanisms, the storage device is characterized in that the guide mechanisms comprise plate bodies, mounting holes and guide portions, the guide portions and the plate bodies enclose a U-shaped groove with a downward opening, the mounting holes are formed in the plate bodies, the guide mechanisms are hung and buckled on the upper end faces of the second side walls through the U-shaped groove, the plate bodies and the mounting holes are located in the containing cavity, the left end and the right end of the first separating frame are inserted into the mounting holes, and the guide portions are located on the outer sides of the second side walls, the guide mechanism can slide back and forth along the upper end surface of the second side wall to drive the first separation frame to slide synchronously; the adjustment assembly includes:

the first adjusting mechanism is matched and connected with one of the first separating frame and the second separating frame to form a first concave-convex curved surface;

the second adjusting mechanism is matched and connected with the other one of the first separating frame and the second separating frame to form a second concave-convex curved surface;

the first adjusting mechanism and the second adjusting mechanism can be connected in a relative rotating mode around a vertical shaft to drive the second partition frame and the first partition frame to rotate relatively, the second concave-convex curved surface and the first concave-convex curved surface are in butt joint and matching with each other when the second partition frame and the first concave-convex curved surface rotate relatively, so that the first adjusting mechanism and the second adjusting mechanism are relatively far away from each other in the vertical direction, and meanwhile one of the first partition frame and the second partition frame is elastically deformed to drive the first adjusting mechanism and the second adjusting mechanism to have a movement trend of being close to each other in the vertical direction.

2. The storage device according to claim 1, wherein when the guide mechanism is hooked at the upper end surface of the second side wall, the relative movement of the guide mechanism and the second side wall in the left-right direction is restricted; when the first partition frame is connected to the guide mechanism, the relative movement of the first partition frame and the guide mechanism in the left-right direction is restricted.

3. The storage device as claimed in claim 1, wherein the second frame is rotatable about the vertical axis relative to the first frame to switch the storage device between the stacked configuration and the unfolded configuration; when the storage device is in the stacking state, the separating surface of the second separating frame is coplanar with the separating surface of the first separating frame; when the storage device is in the unfolded state, the separating surface of the second separating frame is perpendicular to the separating surface of the first separating frame.

4. A storage device as claimed in claim 3, characterized in that said adjustment assembly has a first engagement condition corresponding to said superimposed condition, a second engagement condition corresponding to said unfolded condition and a threshold condition between said first and second engagement conditions; when the second separating frame and the first separating frame rotate relatively, the adjusting assembly is subjected to an elastic driving force, and the elastic driving force drives the adjusting assembly to change from the critical state to the first meshing state or the second meshing state.

5. The storage device of claim 1, wherein said second divider is further slidably coupled to said first divider by said adjustment assembly.

6. The storage device according to claim 1, wherein the first partition shelf includes a partition rail extending in a left-right direction and partitioning the receiving cavity, and the second partition shelf includes a partition vertical bar partitioning the receiving cavity; the adjusting assembly comprises a first channel and a second channel, wherein the first channel is used for one of the separating transverse rod and the dividing longitudinal rod to pass through in a sliding mode, and the second channel is used for the other one of the separating transverse rod and the dividing longitudinal rod to pass through in a sliding mode.

7. A refrigerator, characterized in that it comprises a storage device according to any one of claims 1 to 6.

Images