CN210141722U

CN210141722U - Water inlet control valve for ice making box of refrigerator, ice making box and refrigerator

Info

Publication number: CN210141722U
Application number: CN201822003060.5U
Authority: CN
Inventors: 费斌; 程学丽
Original assignee: Shenyang Fridge Co Ltd Of Haier
Current assignee: Shenyang Fridge Co Ltd Of Haier
Priority date: 2018-11-30
Filing date: 2018-11-30
Publication date: 2020-03-13
Anticipated expiration: 2028-11-30

Abstract

The utility model relates to a water inlet control valve, ice making box and refrigerator for refrigerator ice making box. The water inlet control valve includes: one end of the rotating arm is rotatably arranged, and the other end of the rotating arm is provided with a valve core; the valve core is configured to block the water inlet of the ice making box; the pressing lug is arranged on the upper side of the rotating arm; the reset elastic arm is arranged at one end of the rotating arm and extends downwards from one end of the rotating arm and towards the direction far away from the valve core; the limiting assembly is provided with a first limiting block and a second limiting block; the lower end of the reset elastic arm is arranged between the first limiting block and the second limiting block, so that when the pressing lug presses downwards, the lower end of the reset elastic arm moves towards the valve core and the reset elastic arm arches towards the direction far away from the valve core, and the reset elastic arm stores energy to enable the rotating arm to reset. The water inlet can be easily opened and automatically closed due to the rotary arm and the reset elastic arm, and the opening and the closing are particularly convenient.

Description

Water inlet control valve for ice making box of refrigerator, ice making box and refrigerator

Technical Field

The utility model relates to a refrigeration plant field especially relates to a water inlet control valve, ice making box and refrigerator for refrigerator ice making box.

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. Furthermore, there is a complicated manual ice maker on the market, which has a case and an ice tray structure provided to the case. The box body is also provided with a water inlet, the water inlet is provided with a plug, and the plug is required to be manually taken down when water is injected at each time, so that the water injection box is very inconvenient.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the first aspect aims at overcoming at least one defect of current refrigerator ice-making, provides a water inlet control valve for refrigerator ice-making box, and its control is convenient, is convenient for open and close the water inlet.

The utility model discloses the purpose of second aspect provides an ice-making box with above-mentioned water inlet control valve.

The utility model discloses the purpose of third aspect provides a refrigerator with above-mentioned ice-making box.

According to the utility model discloses an aspect, the utility model provides a water inlet control valve for refrigerator ice making box, it includes:

one end of the rotating arm is rotatably arranged, and the other end of the rotating arm is provided with a valve core; the valve core is configured to block the water inlet of the ice making box;

the pressing lug is arranged on the upper side of the rotating arm;

the reset elastic arm is arranged at one end of the rotating arm, and extends downwards from one end of the rotating arm and towards the direction far away from the valve core; and

the limiting assembly is provided with a first limiting block and a second limiting block; the lower end of the reset elastic arm is arranged between the first limiting block and the second limiting block, so that when the pressing lug presses downwards, the lower end of the reset elastic arm moves towards the valve core and the reset elastic arm arches towards the direction far away from the valve core, and the reset elastic arm stores energy to drive the rotating arm to reset.

Optionally, the first limit block is disposed on one side of the reset elastic arm facing the valve core;

the second limiting block is arranged on the other side of the reset elastic arm; and is

The first limiting block is connected with the reset elastic arm at a distance between one ends of the rotating arms, and the second limiting block is connected with the reset elastic arm at a distance between one ends of the rotating arms.

Optionally, the first stopper and the second stopper each include:

the surface of the base block facing the resetting elastic arm is a curved surface arched towards the resetting elastic arm; and

the bar-shaped block extends out of the bending surface and extends along the axial direction of the bending surface; the strip-shaped block is contacted with the reset elastic arm to abut against the reset elastic arm.

Optionally, the surface of the bar block contacting the return spring arm is a portion of the cylindrical profile.

Optionally, the upper surface of the valve element is a blocking surface, and the blocking surface is in contact with the lower edge of the water inlet to abut against the lower edge of the water inlet so as to block the water inlet of the ice making box.

Optionally, the blocking surface is a curved surface, and the height of the curved surface gradually decreases along the extending direction of the rotating arm towards the valve core.

According to the utility model discloses a second aspect, the utility model provides an ice-making box, it includes:

the water inlet and the through hole are formed in the top wall of the box body;

any one of the water inlet control valves is arranged in the box body, and the pressing lug of the water inlet control valve extends out of the through hole; and

at least one ice grid structure member, set up in the box body, the water inlet directly or indirectly with every ice grid structure member intercommunication.

Optionally, the number of the ice tray structural members is multiple, and the ice tray structural members are sequentially arranged along the up-down direction to form multiple layers of ice trays;

each ice grid structure part is provided with a plurality of ice grids, water grids, at least one first communicating water channel and at least one second communicating water channel;

each first communication water channel is communicated with the upper ends of two adjacent ice grids so that each ice grid structural member has at least one water flow path, and the first ice grid of at least one water flow path is the same ice grid so that ice making water is filled in the first ice grid on each water flow path and then sequentially filled in the rest ice grids through at least one first communication water channel;

each second communication water channel is communicated with the upper end of the last ice grid on one water flow path and the upper end of the water passing grid;

in two adjacent ice grid structural members, the water passing grid of the upper ice grid structural member is positioned right above the first ice grid on at least one water flow path of the lower ice grid structural member;

the water inlet is positioned right above the first ice tray on at least one water flow path of the uppermost ice tray structure.

Optionally, the ice-making box further comprises a water cup and an ice storage box; the water cup is placed in the box body; the ice storage box is movably arranged in the box body and is positioned at the lowest part of the lower side of the ice grid structural part.

According to the utility model discloses a third aspect, the utility model provides a refrigerator, including the box and the door body to and any kind of above-mentioned ice making box, the ice making box install in or place in the box or the internal side of door.

The utility model discloses a water inlet control valve, ice making box and refrigerator for refrigerator ice making box, owing to have the rocking arm and reset the elastic arm, the water inlet can easily be opened and self-closing, and it is very convenient to open and close.

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 present invention will be described in detail hereinafter, by way of illustration and not by way of 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 block diagram of a water inlet control valve according to an embodiment of the present invention;

FIG. 2 is a schematic block diagram of a water inlet control valve according to an embodiment of the present invention;

fig. 3 is a schematic exploded view of a water inlet control valve according to an embodiment of the present invention;

fig. 4 is a schematic structural view of an ice making housing according to an embodiment of the present invention;

fig. 5 is a schematic configuration view of the ice making housing of fig. 4 in a state where a turnover door is opened;

fig. 6 is a schematic exploded view of the ice making housing shown in fig. 4;

fig. 7 is a schematic structural view of an ice grid structure in an ice making housing according to an embodiment of the present invention;

fig. 8 is a schematic structural view of a water injection process in an ice making housing according to an embodiment of the present invention;

fig. 9 is a schematic structural view of a plurality of ice grid structures in an ice-making housing according to an embodiment of the present invention;

fig. 10 is a schematic structural view of a case body in an ice making housing according to an embodiment of the present invention;

fig. 11 is a schematic cross-sectional view of an ice making housing according to an embodiment of the present invention.

Detailed Description

Fig. 1 is a schematic block diagram of a water inlet control valve according to an embodiment of the present invention. As shown in fig. 1 and referring to fig. 2 to 3, an embodiment of the present invention provides a water inlet control valve 60 for an ice making box of a refrigerator, which includes a rotation arm 61, a pressing protrusion 62, a return elastic arm 63, and a limit assembly 64. One end of the rotating arm 61 is rotatably provided, and the other end of the rotating arm 61 is provided with a valve core 69. The valve core 69 is configured to block the water inlet 22 of the ice making box. The pressing projection 62 is provided on the upper side of the rotation arm 61 to press the rotation arm 61, so that the valve body 69 is rotated downward to open the water inlet 22. The return spring arm 63 is provided at the one end of the pivot arm 61, and extends downward from the one end of the pivot arm 61 in a direction away from the valve body 69.

The stop assembly 64 has a first stop block 65 and a second stop block 66. The lower end of the reset elastic arm 63 is disposed between the first stopper 65 and the second stopper 66, so that when the pressing protrusion 62 is pressed downward, the valve core 69 rotates downward, the lower end of the reset elastic arm 63 moves toward the valve core 69 and the reset elastic arm 63 arches in a direction away from the valve core 69, so that energy is stored to urge the rotating arm 61 to reset. When the automatic closing valve works, the pressing bump 62 presses downwards, the valve core 69 rotates downwards, under the action of the limiting assembly 64, the lower end of the resetting elastic arm 63 moves towards the valve core 69, and the resetting elastic arm 63 arches towards the direction far away from the valve core 69, so that the resetting elastic arm 63 stores energy to drive the rotating arm 61 to reset, and further the automatic closing of the water inlet 22 can be realized.

In some embodiments of the present invention, the first stopper 65 is disposed on one side of the elastic arm 63 facing the valve core 69. The second stopper 66 is disposed on the other side of the elastic arm 63. And the distance between the first stopper 65 and the end of the return elastic arm 63 connected to the rotating arm 61 is smaller than the distance between the second stopper 66 and the end of the return elastic arm 63 connected to the rotating arm 61.

Further, the first stopper 65 and the second stopper 66 each include a base block and a bar-shaped block. The surface of the base block facing the return spring arm 63 is a curved surface that arches toward the return spring arm 63. The bar-shaped blocks extend from the curved surface and extend in the axial direction of the curved surface. The bar is in contact abutment with the return resilient arm 63. After the return spring arm 63 is bent, the return spring arm 63 may be in contact with and abutted against the two base blocks. Preferably, the surface of the bar-shaped block in contact with the return elastic arm 63 is part of the cylindrical surface.

In some embodiments of the present invention, the upper surface of the valve core 69 is a blocking surface, and contacts with the lower edge of the water inlet 22 to abut against the blocking surface to block the water inlet 22 of the ice making box. Alternatively, the blocking surface is a curved surface, and the height of the curved surface gradually decreases in the extending direction of the rotating arm 61 toward the spool 69 and gradually decreases in the radial direction of the water inlet 22. The lower end structure of the water inlet 22 can be adapted to the blocking surface to better achieve blocking.

The embodiment of the present invention further provides an ice making box, as shown in fig. 4 to 11, the ice making box may include a box body 20, a water inlet control valve 60 and at least one ice tray structure 30 in any of the above embodiments. The top wall of the box body 20 is provided with a water inlet 22 and a through hole. The water inlet control valve 60 is installed in the box body 20, and the pressing projection 62 of the water inlet control valve 60 extends out of the through hole, so that a user can conveniently press and open the through hole. At least one ice grid structure 30 is disposed in the box body 20, and the water inlet 22 is directly or indirectly communicated with each ice grid structure 30. Preferably, the ice tray structure 30 is provided in plurality, and is sequentially arranged along the up-down direction to form a plurality of ice trays.

In some embodiments of the present invention, the front side of the box body 20 is provided with a front opening. The front opening is rotatably provided with a turnover door 21 to make the box body 20 in a closed structure. Each ice tray structure 30 is detachably mounted to the box body 20 so as to be taken down from the box body 20 or mounted to the box body 20 through the front opening, and the ice tray structure 30 is detachably mounted to the box body 20 so that the ice trays are conveniently detached and cleaned.

In some embodiments of the present invention, each ice grid structure 30 has a plurality of ice grids 31, a water passage grid 32, at least one first water passage 33 and at least one second water passage. Each of the first communication channels 33 communicates upper ends of two adjacent ice trays 31, so that each of the ice tray structures 30 has at least one water flow path, and the first ice tray 31 of the at least one water flow path is the same ice tray 31, so that the ice making water sequentially fills the remaining ice trays 31 through the at least one first communication channel 33 after filling the first ice tray 31 of each water flow path. Each of the second communication channels communicates an upper end of the last ice tray 31 and an upper end of the water passing tray 32 on one water flow path. In two adjacent ice grid structures 30, the water passing grid 32 of the upper ice grid structure 30 is positioned right above the first ice grid 31 on at least one water flow path of the lower ice grid structure 30.

For example, the water flow path of each ice tray structure 30 may be one, each first water passage 33 communicates with the upper ends of two adjacent ice trays 31, and each ice tray 31 communicates with only one remaining ice tray 31, so that the ice making water sequentially fills the remaining ice trays 31 through at least one first water passage 33 after filling the first ice tray 31 on the water flow path. The second communication waterway communicates an upper end of the last ice tray 31 and an upper end of the water passing tray 32 on the water flow path. In two adjacent ice grid structural members 30, the water passing grid 32 of the upper ice grid structural member 30 is positioned right above the first ice grid 31 on the corresponding water flow path of the lower ice grid structural member 30, so that after each ice grid 31 in the upper ice grid structural member 30 is filled with water, the water enters the lower ice grid structural member 30 through the water passing grid 32, and the ice grids 31 in the lower ice grid structural member 30 are filled with water. Of course, the water flow path of each ice grid structure 30 may be multiple, and the number of the ice grids 31 passing through each water flow path is as equal as possible or not different.

Each ice tray 31 may have a full lattice line for storing water, the first communicating water passage 33 and the second communicating water passage are both water chutes, the water chutes may be located at the upper side of the full lattice line, and all the ice trays 31 may be sequentially filled with the first communicating water passage 33 and the second communicating water passage.

In some embodiments of the present invention, the ice bank further includes a water cup 50 and an ice bank 40. The cup 50 is placed within the housing 20 and preferably directly below the pass-through grid 32 of the lowermost ice grid structure 30. The ice bank 40 is movably disposed in the case 20 at a lower side of the lowermost ice grid structure 30. Further, the inner side of the bottom wall of the box body 20 is provided with a rotating shaft 24 and an arc-shaped limiting groove 25. A corner of one end of the front side of the ice bank 40 is provided with a rotation hole, which is installed at the rotation shaft 24. The bottom plate of the ice bank 40 has a protrusion extending downward and inserted into the arc-shaped stopper groove 25 so that the ice bank 40 is rotatably mounted to the case 20. The water cup 50 is placed in the ice bank 40. The capacity of the water cup 50 and the water storage capacity of all the ice trays 31 in each ice tray structure 30 may be the same, for example, 180ml each, so that each cup of water can be used for filling one layer of ice tray 31.

In some embodiments of the present invention, the water inlet 22 is located directly above the first ice grid 31 in the corresponding water flow path of the uppermost ice grid structure 30. The rotation arm 61 is disposed inside the case 20, and one end of the rotation arm 61 is rotatably mounted to the case 20. The stopper assembly 64 is provided on the rear wall of the case 20. The rotatable arm 61 can be rotated downward by about 7 deg.c. When the pressing protrusion 62 is pressed, the rotating arm 61 rotates downward, the valve core 69 moves, the water inlet 22 is opened, and the return elastic arm 63 is deformed by the first stopper 65 and the second stopper 66. When water is not injected, the pressing lug 62 is released, and the valve core 69 and the rotating arm 61 are reset under the action of the reset elastic arm 63 to block the water inlet 22.

In some embodiments of the present invention, the plurality of ice trays 31 and the water trays 32 of each ice tray structure 30 are arranged in at least one row in the front-rear direction and in a plurality of rows in the lateral direction. And, when the plurality of ice trays 31 and water trays 32 of each ice tray structure 30 are arranged in a row in the front-rear direction, the corresponding water flow path is preferably one and linear. When the plurality of ice trays 31 and the water trays 32 of each ice tray structure 30 are arranged in at least two rows in the front-rear direction, the corresponding water flow path may be one and have a serpentine shape. Alternatively, when the plurality of ice trays 31 and water trays 32 of each ice tray structure 30 are arranged in two rows in the front-rear direction, the corresponding water flow paths may be two, and the water trays 32 are disposed diagonally to the first ice tray 31 of the two water flow paths, and the number of ice trays 31 through which each water flow path flows is equal, as shown in fig. 7.

In some embodiments of the present invention, as shown in fig. 9, each ice grid structure 30 has the same structure, and when being installed on the box body 20, the relative positions of the front and back sides of two adjacent ice grid structures 30 are reversed and the relative positions of the two transverse ends are reversed. That is, two ice grid structures 30 adjacent to each other up and down are installed with a 180 ° rotation therebetween. Furthermore, a special structure can be designed for installation, the user does not need to rotate the rotary table intentionally, and the rotary table has universality.

In some specific embodiments of the present invention, two installation shafts 36 are disposed on both end surfaces of each ice grid structure 30, two installation shafts 36 are disposed at the front and rear ends of the corresponding end surface, and one installation shaft 36 is higher than the other installation shaft 36.

The two side walls of the box body 20 are provided with a plurality of mounting groove sets which are sequentially arranged along the vertical direction, and each mounting groove set comprises two first grooves 27 and two second grooves 28. Two first grooves 27 are provided on the two side walls, respectively. And the front end of each first groove 27 has a first opening. Two second grooves 28 are provided on the two side walls, respectively. And the front end of each second groove 28 has a second opening. The second slot 28 extends rearwardly from the second opening for a length less than the length of the first slot 27 extending rearwardly from the first opening. In every two adjacent mounting slot groups, the first slot 27 in one mounting slot group is located at the upper side of the second slot 28, and the first slot 27 in the other mounting slot group is located at the lower side of the second slot 28.

Each ice grid structure 30 is mounted to a set of mounting slots by four mounting shafts 36 thereon. Specifically, when installed, each ice grid structure 30 is mounted to the upper mounting groove (the first groove 27 or the second groove 28) by the two mounting shafts 36 on the upper side, and each ice grid structure 30 is mounted to the lower mounting groove (the second groove 28 or the first groove 27) by the two mounting shafts 36 on the lower side.

In order to ensure the stability of the installation of each ice grid structure 30 and to facilitate the disassembly and installation, the rear end of each first groove 27 and each second groove 28 has a limiting structure to prevent the installation shaft 36 installed therein from sliding forward. The limiting structure is a recess arranged at the rear end of the bottom surface of the first groove 27 or the rear end of the bottom surface of the second groove 28; and/or, a limit rib provided at the rear end of the bottom surface of the first groove 27 or the rear end of the bottom surface of the second groove 28; and/or a stopper rib provided at the rear end of the top surface of the first groove 27 or the rear end of the top surface of the second groove 28.

In the ice making box provided by the embodiment of the utility model, the ice making quantity is large due to the multi-layer ice grids 31; each layer of ice tray 31 is detachably mounted, is convenient to clean and can be repeatedly used; and during water injection, the ice grids 31 from the upper layer to the lower layer can be filled in sequence, the water injection is simple and convenient, and only the water injection is carried out on the ice grid 31 on the uppermost layer, so that the ice making requirement of most people can be met, and the large ice quantity requirement of national family users such as southeast Asia and the like can also be met.

The embodiment of the utility model provides a refrigerator is still provided, the ice-making box in the embodiment of box, door body and above-mentioned arbitrary. 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 shown and described in detail herein, many other variations and modifications can be made, consistent with the principles of the invention, which are directly determined or derived from the disclosure herein, without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should be understood and interpreted to cover all such other variations or modifications.

Claims

1. A water inlet control valve for an ice making housing of a refrigerator, comprising:

the pressing lug is arranged on the upper side of the rotating arm;

2. The water inlet control valve of claim 1,

the first limiting block is arranged on one side, facing the valve core, of the reset elastic arm;

3. The water inlet control valve according to claim 1 or 2, characterized in that the first stopper and the second stopper each comprise:

4. The water inlet control valve of claim 3,

the surface of the strip block, which is contacted with the reset elastic arm, is a part of the cylindrical profile.

5. The water inlet control valve of claim 1,

the upper surface of the valve core is a blocking surface and is contacted and abutted with the lower edge of the water inlet so as to block the water inlet of the ice making box.

6. The water inlet control valve of claim 5,

the blocking surface is a curved surface, and the height of the curved surface is gradually reduced along the extension direction of the rotating arm towards the valve core.

7. An ice making box, comprising:

the water inlet control valve of any one of claims 1 to 6, mounted within the cartridge body with a pressing lug of the water inlet control valve protruding out of the through hole; and

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

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

9. The ice-making housing of claim 8, further comprising a water cup and an ice bank;

the water cup is placed in the box body; the ice storage box is movably arranged in the box body and is positioned at the lowest part of the lower side of the ice grid structural part.

10. A refrigerator, comprising a refrigerator body and a door body, characterized in that, the refrigerator further comprises an ice-making box according to any one of claims 7 to 9, wherein the ice-making box is mounted or placed in the refrigerator body or inside the door body.