CN111336733A - Ice making box for refrigerator and refrigerator - Google Patents

Abstract

The invention relates to an ice-making box for a refrigerator and the refrigerator. The ice-making box includes: the front side of the box body is provided with an installation opening; the ice grid structural members are sequentially arranged along the vertical direction to form a plurality of layers of ice grids; and each ice tray structural part is detachably arranged in the box body through one first mounting structure. Due to the fact that the ice tray structure is provided with the first mounting structure, the ice tray structure can be quickly and conveniently disassembled and assembled, and is convenient to disassemble, and further the ice tray is convenient to clean. The multi-layer ice tray can make the ice making quantity large.

Description

Ice making box for refrigerator and refrigerator

Technical Field

The invention relates to the field of refrigeration equipment, in particular to an ice making box for a refrigerator and the refrigerator.

Background

At present, a refrigerator in a home uses an ice making housing combined by a plurality of small molds when making ice cubes. Such ice making boxes suffer from the following disadvantages: due to the relatively small space of the refrigerator, the ice making box occupies relatively valuable space of the freezing chamber of the refrigerator in use. Because of the relatively small once ice making amount, when more ice blocks need to be frozen, the refrigerator needs to be opened for many times, so that a plurality of repeated operations and high energy loss are caused; moreover, water is easy to spill during water injection. In addition, a complicated manual ice maker is available in the market, and because the ice maker needs to be provided with a torsion spring at one end of an ice tray to realize ice removal, the ice tray and the torsion spring are required to be fixed at one end of a shell, and the other end of the ice tray is required to realize rotary ice removal. The ice tray can not be disassembled and cleaned.

Disclosure of Invention

An object of a first aspect of the present invention is to overcome at least one of the disadvantages of the existing refrigerator in making ice, and to provide an ice-making housing for a refrigerator, which has a large ice-making amount.

It is a further object of the first aspect of the invention to facilitate cleaning of the ice tray of the ice-making housing.

It is a further object of the first aspect of the invention to facilitate filling of the ice grid of the ice-making housing.

A second aspect of the present invention is to provide a refrigerator having the ice-making housing.

According to a first aspect of the present invention, there is provided an ice-making housing for a refrigerator, including:

a box body;

the ice grid structural members are sequentially arranged along the vertical direction to form a plurality of layers of ice grids; and

and each ice tray structural part is arranged in the box body through one first mounting structure.

Optionally, each ice grid structure is detachably mounted in the box body through the corresponding first mounting structure; and the ice-making housing further comprises:

the ice storage box is arranged at the lower sides of the ice grid structural parts; and

the second mounting structures are arranged at the lower sides of the first mounting structures and are positioned at the upper side of the ice storage box; and the second mounting structure is configured to enable the ice grid structural member to be mounted on the second mounting structure after the ice grid structural member is taken out from the corresponding first mounting structure, and drive the ice grid structural member to rotate for deicing.

Optionally, the front side, the rear side or both sides of the box body are provided with mounting openings;

the second mounting structure and each of the first mounting structures are configured to enable the corresponding ice grid structure to be horizontally inserted into the box body through the mounting opening.

Optionally, the front side or the rear side of the box body is provided with an installation opening;

one end of each ice grid structural member is provided with an installation block, and the other end of each ice grid structural member is provided with an installation shaft; and the number of the first and second electrodes,

the second mounting structure and each of the first mounting structures include:

a horizontally extending slot such that the mounting block is horizontally inserted into the slot; the clamping groove of each first mounting structure is directly formed on one vertical side wall of the box body, or the clamping groove of each first mounting structure is formed on the side surface of a mounting piece facing the inside of the box body, and the mounting piece is mounted on one vertical side wall of the box body; the clamping groove of each second mounting structure is formed on the side surface, facing the interior of the box body, of the first rotating piece, and the first rotating piece is rotatably mounted on one vertical side wall of the box body;

a mounting groove horizontally provided inside the other vertical sidewall of the case body to allow the mounting shaft to be inserted from the front and moved backward;

the block hole is arranged on the other vertical side wall of the box body;

and a stopper installed in the stopper hole to block forward movement of the mounting shaft by being inserted from the stopper hole after the mounting shaft is inserted into the mounting groove in a backward direction and moved backward.

Optionally, the second mounting structure further includes a second rotating member disposed outside the box body and connected to the first rotating member, so that the first rotating member drives the ice tray structure to rotate from the initial position to the ice-shedding position.

Optionally, the second mounting structure further comprises:

a reset device configured to cause the ice grid structure to rotate towards the initial position; and

and the limiting device is configured to block the ice grid structural member from continuing to rotate after the ice grid structural member rotates to the initial position.

Optionally, the return device is a torsion spring;

a first annular convex rib is arranged on the side surface of the first rotating member facing the box body, a second annular convex rib is arranged on the inner surface of the corresponding vertical side wall of the box body, and the first annular convex rib is arranged on the inner side of the second annular convex rib so as to rotate along the second annular convex rib; and the stop device includes:

the first limiting block is arranged on the first rotating piece and is positioned on the inner side of the first annular convex rib;

the second limiting block is arranged on the box body and is positioned on the inner side of the second annular convex rib so as to be matched with the first limiting block;

the third limiting block is arranged on the upper side of the mounting groove of the second mounting structure and is provided with an arc-shaped guide surface and a limiting surface positioned at the upper end of the arc-shaped guide surface; and

and the fourth limiting block is arranged at one end, provided with the installation shaft, of the ice grid structural member and is positioned on the upper side of the installation shaft, so that when the ice grid structural member rotates from the ice removing position to the initial position, the ice grid structural member moves to be in contact with the limiting surface along the arc-shaped guide surface.

Optionally, the stopper and the rear end of the mounting groove define a mounting hole of the mounting shaft;

a plurality of limiting convex ribs are arranged on the peripheral wall of the stop block; a plurality of limiting grooves are formed in the hole wall of the block hole and matched with the limiting convex ribs; one end of the stop block, which is positioned at the outer side of the box body, is provided with a limiting cover, and the other end of the stop block is provided with a limiting buckle; the middle parts of the two sides of the mounting block are provided with limiting holes; the clamping groove comprises two clamping plates which are oppositely arranged, and a protrusion matched with the limiting hole is arranged in the middle of each clamping plate.

Optionally, the ice-making housing further includes a water injection device having:

the water injection cavity is arranged on the upper sides of the ice grid structural parts; the upper end of the peripheral wall of the water injection cavity is provided with a plurality of water injection ports;

the upper end of each water injection pipe is connected with one water injection port, and the lower end of each water injection pipe faces one ice lattice structural member so as to inject water into the ice lattice structural member; and

the water injection pressing block is arranged at the upper end of the water injection cavity; the peripheral wall of the water injection pressing block is provided with a plurality of flow channels, each flow channel is arranged corresponding to one water injection port, so that when the water injection pressing block moves downwards to press water in the water injection cavity, the water in the water injection cavity enters the corresponding water injection port through each flow channel and further enters each ice lattice structural part through the corresponding water injection pipe.

According to a second aspect of the present invention, the present invention provides a refrigerator, which includes a refrigerator body, a door body, and any one of the ice-making housings described above, wherein the ice-making housing is mounted or placed in the refrigerator body or inside the door body.

The ice making box and the refrigerator provided by the invention have the advantages that the ice making quantity per time is large due to the multiple layers of ice grids. The ice making machine can meet the ice making requirements of most people and can also meet the large ice quantity requirements of domestic users in southeast Asia and other countries.

Furthermore, the ice making box and the refrigerator provided by the invention have the first mounting structure, so that the ice tray structural member can be quickly and conveniently dismounted, and the ice tray is convenient to clean and can be repeatedly used. Furthermore, the ice making box and the refrigerator are convenient to ice-shed due to the second mounting structure and the ice storage box.

Furthermore, in the ice making box and the refrigerator, due to the special structure of the water injection device, water injection is convenient, injection of each layer of ice grids can be realized by one-time pressing, the water injection is uniform, and the water quantity of each layer of ice grids is basically consistent.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic structural view of an ice making housing according to one embodiment of the present invention;

fig. 2 is a schematic partial structural view of the ice making housing shown in fig. 1;

fig. 3 is a schematic exploded view of the ice-making housing shown in fig. 1;

fig. 4 is a schematic configuration view of an ice-shedding process of the ice-making housing shown in fig. 1;

fig. 5 is a schematic configuration view of an ice-shedding process of the ice-making housing shown in fig. 1;

fig. 6 is a schematic partial structural view of a water filling means in the ice making housing of fig. 1;

FIG. 7 is a schematic view of a pressing block for filling water in the water filling apparatus shown in FIG. 6;

FIG. 8 is a schematic top view of a water injection process of the water injection apparatus of FIG. 6;

FIG. 9 is a schematic side view of a water injection process of the water injection apparatus of FIG. 6;

FIG. 10 is a schematic side view of a water injection process of the water injection device of FIG. 6.

Detailed Description

Fig. 1 is a schematic structural view of an ice making housing according to one embodiment of the present invention. As shown in fig. 1 and referring to fig. 2 to 10, an embodiment of the present invention provides an ice making case. The ice-making housing may include a housing body 20, a plurality of ice grid structures 30, and a plurality of first mounting structures 40. The case 20 has a mounting opening at a front side, a rear side, or both sides. Preferably, the mounting opening is provided at the front side of the case 20. Each ice grid structure 30 has a plurality of ice grids. The plurality of ice grid structures 30 are sequentially arranged in an up-down direction to form a multi-layered ice grid. And each ice grid structure 30 is mounted in the box body 20 by a first mounting structure 40. Preferably, each ice grid structure 30 is removably mounted within the case 20 by a respective first mounting structure 40. The ice tray of the ice making box in the embodiment of the invention is detachable and convenient to clean, and the ice making quantity of the multiple layers of ice trays is large. Further, a door 21 may be provided at the mounting opening to close the case 20 as much as possible.

In some embodiments of the present invention, the ice-making housing further includes an ice bank 50 and a second mounting structure 60. The ice bank 50 is disposed at a lower side of the plurality of ice grid structures 30. The second mounting structure 60 is disposed at a lower side of the plurality of first mounting structures 40 and at an upper side of the ice bank 50. And the second mounting structure 60 is configured to mount one ice grid structure 30 to the second mounting structure 60 after the ice grid structure 30 is removed from the corresponding first mounting structure 40, and to rotate the ice grid structure 30 for deicing, as shown in fig. 4 and 5. That is, when ice removal is required after ice making is completed, the ice grid structure 30 may be removed from the first mounting structure 40 and mounted on the second mounting structure 60, and after ice removal is completed, the ice grid structure 30 may be removed from the second mounting structure 60 and mounted on the corresponding first mounting structure 40. The ice tray of each layer can be changed to the lowest layer for deicing. The ice making and the ice removing are separated, the convenience is realized, and the space is saved.

In some embodiments of the present invention, the second mounting structure 60 and each first mounting structure 40 are configured to allow the corresponding ice grid structure 30 to be inserted horizontally into the box 20 through the mounting opening. That is, the ice grid structure 30 is inserted into the box body 20 in a horizontal state during installation, so that the ice grid structure is convenient to assemble and disassemble.

Specifically, each ice grid structure 30 has a mounting block 31 at one end and a mounting shaft 32 at the other end. The second mounting structure 60 and each first mounting structure 40 may include a mounting member 61, a mounting slot, a stop hole, and a stop 62. The mounting member 61 is mounted to one vertical side wall of the case 20, and a horizontally extending catching groove is provided on a side of the mounting member 61 facing the inside of the case 20 so that the mounting block 31 is horizontally inserted into the catching groove. The mounting groove is horizontally provided inside the other vertical sidewall of the case 20 to allow the mounting shaft 32 to be inserted from the front and moved backward. The blocking block hole is formed in the other vertical sidewall of the case 20. The stop 62 is mounted to the stop hole to block forward movement of the mounting shaft 32 upon rearward insertion of the mounting shaft 32 into the mounting slot and rearward movement thereof. In some alternative embodiments of the present invention, the slot of the first mounting structure 40 may be formed directly inside the vertical sidewall of the box body 20.

Further, the mounting part 61 of the second mounting structure 60 is rotatably mounted to one vertical sidewall of the case 20. The mounting member 61 of the second mounting structure 60 may also be referred to as a first rotating member.

That is, when the ice tray structure 30 is installed, the ice tray structure 30 is horizontally inserted into the slot and the installation groove, and after the ice tray structure is moved backward to a predetermined position (i.e., moved to the rear side of the stopper hole), the stopper 62 is inserted into the stopper hole, so that the ice tray structure 30 is installed conveniently.

In some preferred embodiments of the present invention, the second mounting structure 60 further includes a second rotating member 63 disposed outside the box body 20 and connected to the first rotating member to rotate the first rotating member, i.e., the first rotating member drives the ice tray structure 30 to rotate from the initial position to the ice-shedding position. The second rotatable member may also be a manual rotatable wheel.

Further, the second mounting structure 60 further includes a reset device 64 and a limiting device. The return device 64 is configured to urge the ice grid structure 30 to rotate toward the initial position. The stop device is configured to prevent the ice grid structure 30 from continuing to rotate after the ice grid structure 30 has rotated to the initial position. The returning means 64 is preferably a torsion spring installed between the first rotating member and the case 20 or between the second rotating member and the case 20.

In some embodiments of the present invention, a side of the first rotating member facing the box 20 is provided with a first annular rib, an inner surface of a corresponding vertical side wall of the box 20 is provided with a second annular rib, and the first annular rib is provided inside the second annular rib to rotate along the second annular rib. And the limiting device comprises a first limiting block and a second limiting block. The first limiting block is arranged on the first rotating piece and is positioned on the inner side of the first annular convex rib. The second limiting block is disposed on the box body 20 and is located inside the second annular rib so as to cooperate with the first limiting block. Further, the limiting device can also comprise a fifth limiting block and a sixth limiting block. The fifth limiting block is arranged on the outer surface of the vertical side wall of the box body 20, the sixth limiting block is arranged on one side, facing the box body 20, of the second rotating part, and the fifth limiting block is matched with the sixth limiting block.

In other embodiments of the present invention, the stop means includes a third stop block 65 and a fourth stop block 66. The third stopper 65 is provided at an upper side of the mounting groove and has an arc-shaped guide surface and a stopper surface at an upper end of the arc-shaped guide surface. The fourth stopper 66 is disposed at one end of the ice tray structure 30 having the mounting shaft 32 and on an upper side of the mounting shaft 32 to move along the arc-shaped guide surface to contact the stopper surface when the ice tray structure 30 rotates from the ice shedding position to the initial position. The third stopper 65 is also used to define the mounting groove.

In some embodiments of the present invention, to secure the firmness of the ice making housing, the stopper 62 and the rear end of the mounting groove define a mounting hole of the mounting shaft 32. The stopper 62 is provided with a plurality of limit ribs on a circumferential wall thereof. The hole wall of the block hole is provided with a plurality of limiting grooves to be matched with a plurality of limiting convex ribs. The stopper 62 is provided with a limit cover at one end thereof located outside the case 20 and a limit buckle at the other end thereof. The middle parts of the two sides of the mounting block 31 are provided with limiting holes. The draw-in groove includes the cardboard of two relative settings, and the middle part of every cardboard is provided with spacing hole complex arch.

In some embodiments of the present invention, for convenience of water injection, the ice making housing further includes a water injection device 70, as shown in fig. 3, 6 to 10. The water injection device 70 has a water injection chamber 71, a plurality of water injection pipes 72, and a water injection pressing block 73. The water injection chamber 71 is provided at an upper side of the plurality of ice grid structures 30. For example, in the top wall of the case 20. The upper end of the peripheral wall of the water injection chamber 71 has a plurality of water injection ports 75. Each water injection pipe 72 has an upper end connected to one water injection port 75 and a lower end facing one ice tray structure 30 to inject water into the ice tray structure 30. The water injection pressing block 73 is provided at an upper end of the water injection cavity 71. The water injection pressing block 73 has a plurality of flow passages 74 on a circumferential wall thereof, and each flow passage 74 is provided corresponding to one water injection port 75, so that when the water injection pressing block 73 moves downward to press the water in the water injection cavity 71, the water in the water injection cavity 71 enters the corresponding water injection port 75 through each flow passage 74, and further enters each ice tray structure 30 through the corresponding water injection pipe 72. That is, when the water injection pressing block 73 is pressed downward, the water in the water injection cavity 71 flows upward to each water injection port 75 along each flow passage 74 by the water injection pressing block 73, and further flows into each layer of ice tray. Because the water injection pressing block 73 is adopted, the pressing pressure is consistent, the water quantity entering each water injection port 75 can be ensured to be uniform, and then multiple layers of ice grids can be filled at the same time.

The embodiment of the invention also provides a refrigerator which comprises a refrigerator body, a door body and the ice-making box in any embodiment. The ice making box is arranged or placed in the box body or the inner side of the door body.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been illustrated and described in detail herein, many other variations or modifications consistent with the principles of the invention may be directly determined or derived from the disclosure of the present invention without departing from the spirit and scope of the invention. Accordingly, the scope of the invention should be understood and interpreted to cover all such other variations or modifications.

Claims (10)

1. An ice-making housing for a refrigerator, comprising:

a box body;

the ice grid structural members are sequentially arranged along the vertical direction to form a plurality of layers of ice grids; and

and each ice tray structural part is arranged in the box body through one first mounting structure.

2. The ice-making housing according to claim 1,

each ice grid structural member is detachably arranged in the box body through the corresponding first mounting structure; and the ice-making housing further comprises:

the ice storage box is arranged at the lower sides of the ice grid structural parts; and

the second mounting structures are arranged at the lower sides of the first mounting structures and are positioned at the upper side of the ice storage box; and the second mounting structure is configured to enable the ice grid structural member to be mounted on the second mounting structure after the ice grid structural member is taken out from the corresponding first mounting structure, and drive the ice grid structural member to rotate for deicing.

3. The ice-making housing according to claim 2,

the front side, the rear side or both sides of the box body are provided with mounting openings;

the second mounting structure and each of the first mounting structures are configured to enable the corresponding ice grid structure to be horizontally inserted into the box body through the mounting opening.

4. The ice-making housing according to claim 3,

the front side of the box body is provided with the mounting opening;

one end of each ice grid structural member is provided with an installation block, and the other end of each ice grid structural member is provided with an installation shaft; and the number of the first and second electrodes,

the second mounting structure and each of the first mounting structures include:

a horizontally extending slot such that the mounting block is horizontally inserted into the slot; the clamping groove of each first mounting structure is directly formed on one vertical side wall of the box body, or the clamping groove of each first mounting structure is formed on the side surface of a mounting piece facing the inside of the box body, and the mounting piece is mounted on one vertical side wall of the box body; the clamping groove of each second mounting structure is formed on the side surface, facing the interior of the box body, of the first rotating piece, and the first rotating piece is rotatably mounted on one vertical side wall of the box body;

a mounting groove horizontally provided inside the other vertical sidewall of the case body to allow the mounting shaft to be inserted from the front and moved backward;

the block hole is arranged on the other vertical side wall of the box body;

and a stopper installed in the stopper hole to block forward movement of the mounting shaft by being inserted from the stopper hole after the mounting shaft is inserted into the mounting groove in a backward direction and moved backward.

5. The ice-making housing according to claim 4,

the second mounting structure further comprises a second rotating piece arranged on the outer side of the box body and connected to the first rotating piece so as to drive the ice grid structural piece to rotate from the initial position to the ice shedding position through the first rotating piece.

6. The ice-making housing of claim 5, wherein the second mounting structure further comprises:

a reset device configured to cause the ice grid structure to rotate towards the initial position; and

and the limiting device is configured to block the ice grid structural member from continuing to rotate after the ice grid structural member rotates to the initial position.

7. The ice-making housing according to claim 6,

the reset device is a torsion spring;

a first annular convex rib is arranged on the side surface of the first rotating member facing the box body, a second annular convex rib is arranged on the inner surface of the corresponding vertical side wall of the box body, and the first annular convex rib is arranged on the inner side of the second annular convex rib so as to rotate along the second annular convex rib; and the stop device includes:

the first limiting block is arranged on the first rotating piece and is positioned on the inner side of the first annular convex rib;

the second limiting block is arranged on the box body and is positioned on the inner side of the second annular convex rib so as to be matched with the first limiting block;

the third limiting block is arranged on the upper side of the mounting groove of the second mounting structure and is provided with an arc-shaped guide surface and a limiting surface positioned at the upper end of the arc-shaped guide surface; and

and the fourth limiting block is arranged at one end, provided with the installation shaft, of the ice grid structural member and is positioned on the upper side of the installation shaft, so that when the ice grid structural member rotates from the ice removing position to the initial position, the ice grid structural member moves to be in contact with the limiting surface along the arc-shaped guide surface.

8. The ice-making housing according to claim 4,

the stop block and the rear end of the mounting groove define a mounting hole of the mounting shaft;

a plurality of limiting convex ribs are arranged on the peripheral wall of the stop block;

a plurality of limiting grooves are formed in the hole wall of the block hole and matched with the limiting convex ribs;

one end of the stop block, which is positioned at the outer side of the box body, is provided with a limiting cover, and the other end of the stop block is provided with a limiting buckle;

the middle parts of the two sides of the mounting block are provided with limiting holes;

the clamping groove comprises two clamping plates which are oppositely arranged, and a protrusion matched with the limiting hole is arranged in the middle of each clamping plate.

9. The ice-making housing according to claim 1, further comprising a water injection device having:

the water injection cavity is arranged on the upper sides of the ice grid structural parts; the upper end of the peripheral wall of the water injection cavity is provided with a plurality of water injection ports;

the upper end of each water injection pipe is connected with one water injection port, and the lower end of each water injection pipe faces one ice lattice structural member so as to inject water into the ice lattice structural member; and

the water injection pressing block is arranged at the upper end of the water injection cavity; the peripheral wall of the water injection pressing block is provided with a plurality of flow channels, each flow channel is arranged corresponding to one water injection port, so that when the water injection pressing block moves downwards to press water in the water injection cavity, the water in the water injection cavity enters the corresponding water injection port through each flow channel and further enters each ice lattice structural part through the corresponding water injection pipe.

10. The utility model provides a refrigerator, includes box and door body, its characterized in that still includes:

the ice-making housing of any one of claims 1 to 9, which is mounted or placed inside the cabinet or the door body.

Images