CN111336730A

CN111336730A - Ice maker and refrigerator with same

Info

Publication number: CN111336730A
Application number: CN201811559022.6A
Authority: CN
Inventors: 赵振雨; 朱小兵; 张延庆; 杜启海; 牟国梁; 米波
Original assignee: Qingdao Haier Co Ltd
Current assignee: Qingdao Haier Co Ltd
Priority date: 2018-12-19
Filing date: 2018-12-19
Publication date: 2020-06-26
Also published as: WO2020125052A1

Abstract

The invention discloses an ice maker and a refrigerator with the same, wherein the ice maker comprises: a frame; the ice-making tray is used for making ice and is rotatably arranged in the frame between an ice-making position and an ice-shedding position; the ice maker further comprises: the splash-proof baffles are respectively arranged above the two side walls of the ice making tray, and the transmission device is connected with the ice making tray; each splash-proof baffle is obliquely arranged and extends towards the ice making tray, and the splash-proof baffles are rotatably connected to the frame through baffle rotating shafts arranged on one sides of the splash-proof baffles; the transmission device is used for driving the two splash-proof baffles to rotate in the direction away from the ice-making tray around the rotation axis of the baffle when the ice-making tray rotates from the ice-making position to the ice-shedding position. The ice maker can prevent unfrozen water from overflowing or splashing out of the ice making tray when the refrigerator door is opened or closed; and the splash-proof baffle plate can not obstruct the ice-shedding of the ice-making tray.

Description

Ice maker and refrigerator with same

Technical Field

The invention relates to the field of ice making equipment, in particular to an ice maker and a refrigerator with the same.

Background

At present, in order to facilitate the use of a user, an ice maker is arranged on a door body of a refrigerator for a plurality of refrigerator products, when the refrigerator is used daily, the user needs to frequently open or close the refrigerator door, when the refrigerator door is opened or closed each time, the water which is not frozen in the ice making tray overflows due to the shaking of the door body, and therefore the phenomenon that other parts of the ice maker are frozen is caused. Therefore, the ice maker needs to be provided with a function of preventing water overflowing and splashing.

The existing ice maker generally extends upwards to arrange baffles at two sides of an ice making tray, so that the baffles have poor water overflow prevention effect and can cause blockage when the ice making tray is defrosted.

Disclosure of Invention

The invention aims to provide an ice maker and a refrigerator with the same.

To achieve the above object, an embodiment of the present invention provides an ice maker including: a frame; the ice-making tray is used for making ice and is rotatably arranged in the frame between an ice-making position and an ice-shedding position; the ice maker further comprises: the splash-proof baffles are respectively arranged above the two side walls of the ice making tray, and the transmission device is connected with the ice making tray; each splash-proof baffle is obliquely arranged and extends towards the ice making tray, and the splash-proof baffles are rotatably connected to the frame through baffle rotating shafts arranged on one sides of the splash-proof baffles; the transmission device is used for driving the two splash-proof baffles to rotate in the direction away from the ice-making tray around the rotation axis of the baffle when the ice-making tray rotates from the ice-making position to the ice-shedding position.

As a further improvement of the present invention, the transmission device is further configured to drive the two splash-proof baffles to rotate around the respective baffle rotation axes in a direction approaching the ice-making tray when the ice-making tray rotates from the ice-shedding position to the ice-making position.

As a further improvement of the invention, one end of the ice-making tray is provided with an ice-making tray rotating shaft which is rotatably connected with the frame; the transmission device comprises an ice making disc gear fixedly connected with the ice making disc rotating shaft, a driven gear meshed with the ice making disc gear, and baffle gears respectively fixedly connected with the two overflow-proof baffle rotating shafts and meshed with each other, wherein one baffle gear is coaxially and fixedly connected with the driven gear; when the ice making tray gear rotates along with the ice making tray from the ice making position to the ice removing position, the driven gear and the baffle gear coaxially connected with the driven gear rotate along with the ice making tray gear, and the two anti-overflow baffles are driven to rotate towards the direction far away from the ice making tray respectively.

As a further improvement of the present invention, when the ice tray gear rotates with the ice tray from the ice-shedding position to the ice-making position, the driven gear and the baffle gear coaxially connected to the driven gear rotate along with the ice tray gear, and drive the two anti-overflow baffles to rotate respectively in a direction approaching the ice tray.

As a further improvement of the invention, the driven gear may be selectively engaged with or disengaged from the ice-making tray gear; during the process that the ice-making tray rotates from the ice-making position to the ice-removing position, the driven gear and the ice-making tray gear are disengaged by meshing steering, and the splash-proof baffle correspondingly rotates from a direction far away from the ice-making tray to be stationary relative to the ice-making tray.

As a further improvement of the invention, during the rotation of the ice-making tray from the ice-shedding position to the ice-making position, the driven gear and the ice-making tray gear are engaged by a disengaging rotation direction, and the splash-proof baffle is correspondingly rotated from being stationary relative to the ice-making tray to a direction approaching the ice-making tray.

As a further improvement of the invention, two side walls of the ice making tray perpendicular to the ice making tray rotating shaft are respectively provided with a first guide end plate and a second guide end plate in an upward protruding manner, and the inner side surface of the first guide end plate and the inner side surface of the second guide end plate are respectively contacted with the end parts of the two splash-proof baffles.

As a further improvement of the invention, the ice maker further comprises a motor for driving the ice-making tray to rotate between an ice-making position and an ice-shedding position, and one end of the ice-making tray, which is far away from the rotating shaft of the ice-making tray, is fixedly connected with an output shaft of the motor.

As a further improvement of the invention, the splash-proof baffle comprises a lapping part fixedly connected with the splash-proof rotating shaft and a shielding part extending upwards from the lapping part, and the shielding part is obliquely arranged and extends towards the ice-making tray; when the ice-making tray is located at the ice-making position, the overlapping part is overlapped on the upper surface of the side wall of the ice-making tray.

In another aspect, the invention further provides a refrigerator, which includes a refrigerator body and a door body for opening and closing the refrigerator body, wherein the ice maker is arranged on the inner side of the door body.

Compared with the prior art, the ice maker disclosed by the invention has the advantages that the anti-splashing baffles are arranged above the two side walls of the ice making tray, so that when a user opens or closes the refrigerator door, unfrozen water can be prevented from overflowing or splashing out of the ice making tray; and the transmission device is arranged, so that the splash-proof baffle is driven by the transmission device to be away from the ice-making tray when the ice-making tray rotates to the ice-shedding position, and the ice-shedding of the ice-making tray is not hindered.

Drawings

FIG. 1 is a schematic structural diagram of an ice making machine according to an embodiment of the present invention;

FIG. 2 is an exploded schematic view of an ice maker according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a transmission according to an embodiment of the present invention;

fig. 4 is an enlarged schematic view of a portion a in fig. 1.

Detailed Description

The present invention will be described in detail below with reference to specific embodiments shown in the drawings. These embodiments are not intended to limit the present invention, and structural, methodological, or functional changes made by those skilled in the art according to these embodiments are included in the scope of the present invention.

It will be understood that terms used herein such as "upper," "above," "lower," "below," and the like, refer to relative positions in space and are used for convenience in description to describe one element or feature's relationship to another element or feature as illustrated in the figures. The spatially relative positional terms may be intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures.

As shown in fig. 1-4, an embodiment of the present invention discloses an ice making machine. The ice maker 1 includes: frame 100, ice-making tray 200, splash guard 300 and transmission 400. The ice tray 200 is used to make ice, and the ice tray 200 is rotatably disposed in the frame 100 between an ice making position and an ice releasing position. The splash guards 300 are disposed above two sidewalls of the ice tray, each splash guard 300 is disposed to be inclined and extends toward the ice tray 200, and the splash guards 300 are rotatably connected to the frame 100 by a guard rotating shaft 310 disposed at one side of the splash guard 300. The transmission device 400 is connected to the ice-making tray 200, and the transmission device 400 is configured to drive the two splash guards 300 to rotate around the respective guard rotating shafts 310 in a direction away from the ice-making tray 200 when the ice-making tray 200 rotates from the ice-making position to the ice-shedding position. Specifically, when the refrigerator door is opened and closed, unfrozen water is most easily splashed along both side walls in the length direction of the ice making tray 200, and thus the two splash guards 300 are respectively provided above both side walls in the length direction of the ice making tray 200.

The ice maker disclosed by the invention can prevent unfrozen water from overflowing or splashing out of the ice making tray 200 when a user opens or closes the refrigerator door by arranging the anti-splashing baffles 300 above the two side walls of the ice making tray 200; and the transmission device 400 is provided so that the splash guard 300 is driven by the transmission device 400 to be away from the ice-making tray 200 when the ice-making tray 200 rotates to the ice-shedding position, thereby not hindering the ice-shedding of the ice-making tray 200.

The transmission device 400 is further configured to drive the two splash guards 300 to rotate around the respective guard rotating shafts 310 in a direction approaching the ice-making tray 200 when the ice-making tray 200 rotates from the ice-shedding position to the ice-making position.

Further, an ice tray rotating shaft 210 rotatably connected to the frame 100 is provided at one end of the ice tray 200. The transmission 400 includes an ice-making tray gear 410 fixedly connected to the ice-making tray rotating shaft 210, a driven gear 420 engaged with the ice-making tray gear 410, and barrier gears 430 respectively fixedly connected to the two water flood prevention barrier rotating shafts 310 and engaged with each other, wherein one barrier gear 430 is coaxially and fixedly connected to the driven gear 420. When the ice making tray gear 410 rotates with the ice making tray 200 from the ice making position to the ice releasing position, the driven gear 420 and the damper gear 430 coaxially connected to the driven gear 420 rotate along with the ice making tray, and drive the two overflow preventing dampers 300 to rotate in a direction away from the ice making tray 200, respectively.

Specifically, as shown in fig. 2 to 3, the two shutter gears 430 are a first shutter gear 431 and a second shutter gear 432, respectively, the first shutter gear 431 is coaxially and fixedly connected with the driven gear 420, and the second shutter gear 432 is engaged with the first shutter gear 431. When the ice-making tray 200 rotates from the ice-making position to the ice-releasing position, the ice-making tray gear 410 rotates along with the ice-making tray rotating shaft 210 and drives the driven gear 420 engaged therewith to rotate in the opposite direction, and because the first baffle gear 431 is coaxially and fixedly connected with the driven gear 420, the motion states of the first baffle gear 431 and the driven gear 420 are consistent, and the second baffle gear 432 is in engaged transmission with the first baffle gear 431, so that the first baffle gear 431 and the second baffle gear 432 respectively drive the two baffle rotating shafts 310 to rotate, and finally the two water splash baffles 300 are respectively driven to rotate in the direction away from the ice-making tray 200. Thus, when the ice making tray 200 rotates to ice off, the splash-proof baffle can be driven to be far away from the ice making tray, and interference on the ice making tray can not be generated.

Therefore, the ice maker in the embodiment of the invention does not need to be provided with an additional power device (such as a motor and the like), and the splash-proof baffle can be far away from the ice making tray by utilizing the rotation of the ice making tray and the transmission of the transmission device, thereby being convenient for users to use.

Preferably, when the ice tray gear 410 rotates with the ice tray 200 from the ice-releasing position to the ice-making position, the driven gear 420 and the baffle gear 430 coaxially connected to the driven gear 420 rotate along with the ice tray, and drive the two water overflow preventing baffles 300 to rotate in a direction approaching to the ice tray 200, respectively.

Similarly, in the process that the ice making tray 200 rotates from the ice removing position to the ice making position, the ice making tray gear 410 rotates along with the ice making tray rotating shaft 210 and drives the driven gear 420 engaged therewith to rotate in the opposite direction, and the first shutter gear 431 and the driven gear 420 have the same motion state, so that the second shutter gear 432 is driven to rotate by engagement; finally, the two splash guards 300 are driven to rotate in directions close to the ice tray 200, respectively. In this way, in the ice making position, the two splash guards 300 are disposed above the two sidewalls of the ice making tray 200, and the upper side of the splash guard 300 is obliquely disposed and extends toward the ice making tray 200.

Preferably, the driven gear 420 is selectively engaged with or disengaged from the ice tray gear 410, the driven gear 420 is disengaged from the ice tray gear 410 by the engagement rotation direction during the rotation of the ice tray 200 from the ice making position to the ice releasing position, and the splash guard 300 is correspondingly rotated to be stationary with respect to the ice tray 200 by the rotation in the direction away from the ice tray 200. That is, in the embodiment of the present invention, as shown in fig. 3, the ice tray gear 410 and the driven gear 420 are both provided with teeth only on a portion of the outer surfaces of the gears, when the ice tray 200 is at the ice making position, the ice tray gear 410 and the driven gear 420 are engaged with each other, and after the ice tray 200 rotates to the ice removing position by a certain angle, the ice tray gear 410 and the driven gear 420 are rotated with each other in an engaged manner until the outer surfaces of both gears have no teeth, so that the engagement of both gears is changed into disengagement, at this time, the ice tray continues to rotate to the ice removing position, the driven gear does not rotate with the gear, and the two splash guards 300 do not rotate any more.

Further, during the rotation of the ice tray 200 from the ice-releasing position to the ice-making position, the driven gear 420 and the ice tray gear 410 are engaged by the releasing direction, and the splash guard 300 is correspondingly rotated from being stationary with respect to the ice tray 200 toward the ice tray 200. Specifically, in the embodiment of the present invention, when the ice-making tray 200 is located at the ice-releasing position, the ice-making tray gear 410 and the driven gear 420 are in a releasing state, after the ice-making tray 200 rotates to the ice-making position by a certain angle, the ice-making tray gear 410 rotates to be capable of meshing with teeth on the driven gear 420, at this time, the ice-making tray 200 continues to rotate to the ice-making position, the ice-making tray gear 410 drives the driven gear 420 to perform meshing transmission, and the first baffle gear 431 coaxially connected to the driven gear 420 rotates to drive the two splash baffles to rotate in the direction close to the ice-making tray, respectively. Therefore, the splash-proof baffle does not rotate along with the ice-making tray in the whole process, so that the rotation angle does not need to be too large, and interference with a frame behind the ice-making tray is avoided; in addition, when the ice making tray is turned to the ice making position from the ice removing position, the splash-proof baffle plate does not rotate to interfere with the rotation path of the ice making tray.

Further, the ice maker further comprises a motor 220 for driving the ice making tray 200 to rotate between an ice making position and an ice releasing position, and one end of the ice making tray 200, which is far away from the ice making tray rotating shaft 210, is fixedly connected with an output shaft of the motor 220.

In the embodiment of the present invention, the ice tray 200 is a twisted ice tray, that is, in the ice-shedding process, when the ice tray 200 rotates to a preset position, one end fixedly connected to the output shaft of the motor 220 continues to rotate, and the other end fixedly connected to the ice tray rotating shaft 210 is restricted from rotating, so that the ice tray 200 is twisted and deformed to shed ice. After the ice removal is completed, the motor 220 reversely drives the ice-making tray 200 to rotate and return to the ice-making position. Generally, during the ice-shedding process, one end of the ice-making tray 200 fixedly connected to the output shaft of the motor 220 is twisted by 180 degrees at the maximum, and the other end fixedly connected to the ice-making tray rotating shaft 210 is twisted by 120 degrees at the maximum. Meanwhile, in the ice-shedding process, when the ice-making tray is twisted from 0 degree to 60 degrees, the splash-proof shutter 300 rotates in a direction away from the ice-making tray 200 with the rotation of the ice-making tray 200, and when the ice-making tray 200 is twisted from 60 degrees to 120 degrees, the splash-proof shutter 300 is stationary. Of course, 180 degrees, 120 degrees, and 60 degrees are merely examples in embodiments of the present invention, and other angles may be used in other embodiments.

In the embodiment of the present invention, as shown in fig. 2, a first guide end plate 230 and a second guide end plate 240 are respectively protruded upward from two sidewalls of the ice-making tray 200 perpendicular to the ice-making tray rotating shaft 210, and an inner side surface of the first guide end plate 230 and an inner side surface of the second guide end plate 240 respectively contact with end portions of the two splash guards 300. Two side walls perpendicular to the rotation shaft 210 of the ice making tray are two side walls in the width direction of the ice making tray 200, and the first guide end 230 and the second guide end 240 are disposed thereon, so that inner side surfaces of the two guide end plates are in contact with the splash-proof baffle 300, and the upper parts of four walls surrounding the ice making tray 200 can be shielded, thereby further improving the splash-proof effect of the ice making tray 200.

Further, as shown in fig. 4, the splash guard 300 includes a bridging portion 320 fixedly connected to the splash-proof rotation shaft 310, and a shielding portion 330 extending from the bridging portion 320, wherein the shielding portion 330 is disposed in an inclined manner and extends toward the ice tray 200. When the ice-making tray 200 is located at the ice-making position, the overlapping part 320 overlaps the upper surface of the sidewall of the ice-making tray 200. The overlapping portion 320 may allow the splash guard 300 to contact the upper surface of the sidewall of the ice tray 200, and when a user opens or closes the refrigerator door, water that is not frozen in the ice tray 200 may flow upward along the sidewall of the ice tray 200 when shaking, and the shielding portion 330 that is obliquely disposed may shield the water and allow it to fall back into the ice tray 200, so that the splash guard 300 has a better splash guard effect.

The ice maker disclosed by the invention has the advantages that the anti-splash baffles are arranged above the two side walls of the ice making tray, so that when a user opens or closes the refrigerator door, unfrozen water can be prevented from overflowing or splashing out of the ice making tray; and the transmission device is arranged, so that the splash-proof baffle is driven by the transmission device to be away from the ice-making tray when the ice-making tray rotates to the ice-shedding position, and the ice-shedding of the ice-making tray is not hindered. The splash-proof baffle plate can be far away from the ice making tray by utilizing the rotation of the ice making tray and the transmission of the transmission device without arranging an additional power device (such as a motor and the like), so that the use of a user is facilitated. The first guide end part and the second guide end plate are arranged above the two side walls in the width direction of the ice making disc, the inner side surfaces of the two guide end plates are in contact with the splash-proof baffle plate, the upper parts of the four walls surrounding the ice making disc can be shielded, and the splash-proof effect of the ice making disc 200 is further improved.

It should be understood that although the present description refers to embodiments, not every embodiment contains only a single technical solution, and such description is for clarity only, and those skilled in the art should make the description as a whole, and the technical solutions in the embodiments can also be combined appropriately to form other embodiments understood by those skilled in the art.

The above-listed detailed description is only a specific description of a possible embodiment of the present invention, and they are not intended to limit the scope of the present invention, and equivalent embodiments or modifications made without departing from the technical spirit of the present invention should be included in the scope of the present invention.

Claims

1. An ice making machine comprising: a frame; the ice-making tray is used for making ice and is rotatably arranged in the frame between an ice-making position and an ice-shedding position; characterized in that the ice maker further comprises: the splash-proof baffles are respectively arranged above the two side walls of the ice making tray, and the transmission device is connected with the ice making tray; each splash-proof baffle is obliquely arranged and extends towards the ice making tray, and the splash-proof baffles are rotatably connected to the frame through baffle rotating shafts arranged on one sides of the splash-proof baffles; the transmission device is used for driving the two splash-proof baffles to rotate in the direction away from the ice-making tray around the rotation axis of the baffle when the ice-making tray rotates from the ice-making position to the ice-shedding position.

2. The ice-making machine of claim 1, wherein the transmission device is further configured to drive the two splash guards to rotate around the respective guard rotation axis in a direction approaching the ice-making tray when the ice-making tray rotates from the ice-shedding position to the ice-making position.

3. The ice-making machine of claim 2, wherein one end of the ice-making tray is provided with an ice-making tray rotating shaft rotatably connected to the frame; the transmission device comprises an ice making disc gear fixedly connected with the ice making disc rotating shaft, a driven gear meshed with the ice making disc gear, and baffle gears respectively fixedly connected with the two overflow-proof baffle rotating shafts and meshed with each other, wherein one baffle gear is coaxially and fixedly connected with the driven gear; when the ice making tray gear rotates along with the ice making tray from the ice making position to the ice removing position, the driven gear and the baffle gear coaxially connected with the driven gear rotate along with the ice making tray gear, and the two anti-overflow baffles are driven to rotate towards the direction far away from the ice making tray respectively.

4. The ice maker as claimed in claim 3, wherein when the ice tray gear rotates with the ice tray from the ice-releasing position to the ice-making position, the driven gear and the damper gear coaxially connected to the driven gear rotate and drive the two water overflow preventing dampers to rotate in directions close to the ice tray, respectively.

5. The ice-making machine of claim 3, wherein said driven gear is selectively engageable with or disengageable from said ice-making tray gear; during the process that the ice-making tray rotates from the ice-making position to the ice-removing position, the driven gear and the ice-making tray gear are disengaged by meshing steering, and the splash-proof baffle correspondingly rotates from a direction far away from the ice-making tray to be stationary relative to the ice-making tray.

6. The ice-making machine of claim 5, wherein the driven gear and the ice-making tray gear are engaged by a disengaging direction during the rotation of the ice-making tray from the ice-releasing position to the ice-making position, and the splash shield is correspondingly rotated from being stationary with respect to the ice-making tray to a direction approaching the ice-making tray.

7. The ice-making machine of claim 1, wherein a first guide end plate and a second guide end plate are respectively protruded from two side walls of the ice-making tray perpendicular to the rotation axis of the ice-making tray, and an inner side surface of the first guide end plate and an inner side surface of the second guide end plate are respectively in contact with ends of the two splash guards.

8. The ice-making machine of claim 2, further comprising a motor for driving the ice-making tray to rotate between an ice-making position and an ice-releasing position, wherein one end of the ice-making tray, which is far away from the ice-making tray rotating shaft, is fixedly connected with an output shaft of the motor.

9. The ice maker as claimed in claim 1, wherein the splash guard includes a bridging portion fixedly connected to the splash rotation shaft and a shielding portion extending upward from the bridging portion, the shielding portion being disposed obliquely and extending toward the ice tray; when the ice-making tray is located at the ice-making position, the overlapping part is overlapped on the upper surface of the side wall of the ice-making tray.

10. A refrigerator comprising a cabinet and a door for opening and closing the cabinet, wherein the ice maker according to any one of claims 1 to 9 is provided inside the door.