CN220187170U - Refrigerator with a refrigerator body - Google Patents

Abstract

The utility model provides a refrigerator. The refrigerator includes: a case; the refrigerator inner container is arranged in the refrigerator body and is internally provided with a freezing chamber; the air duct mechanism is arranged in the box body and positioned between the box body and the refrigerator liner, and the side wall of the freezing chamber is provided with an air outlet which is communicated with the air duct mechanism and the freezing chamber; the ice making mechanism is arranged in the freezing chamber and close to the air outlet, and the projection of the ice making mechanism on the side wall is staggered with the air outlet; the wind direction adjusting mechanism is arranged in the freezing chamber and on the air outlet and is used for guiding the cold air led in from the air outlet to different ice making areas of the ice making mechanism. In this way, the utility model can effectively improve the ice making uniformity of the refrigerator and can improve the ice making speed of the refrigerator.

Description

Refrigerator with a refrigerator body

Technical Field

The utility model relates to the technical field of household appliances, in particular to a refrigerator.

Background

As a refrigerating apparatus for preserving foods, a refrigerator has become an indispensable household appliance for people's daily life. The refrigerator freezing layer can be provided with an ice making mechanism for making and storing ice so as to meet the daily living demands of people. At present, the existing refrigerator cannot automatically adjust the ice making speed according to the needs of users, and cannot realize quick ice making; and the air outlet of the existing refrigerator generally uses a fan blade to blow air in a 'wind throwing' mode, so that the ice making effect of the ice making box is uneven, and the ice making speed and the use experience are affected.

Disclosure of Invention

The utility model provides a refrigerator, which can effectively improve the ice making uniformity of the refrigerator and can improve the ice making speed of the refrigerator.

In order to solve the technical problems, the utility model adopts a technical scheme that: provided is a refrigerator including: a case; the refrigerator inner container is arranged in the refrigerator body and is internally provided with a freezing chamber; the air duct mechanism is arranged in the box body and positioned between the box body and the refrigerator liner, and the side wall of the freezing chamber is provided with an air outlet which is communicated with the air duct mechanism and the freezing chamber; the ice making mechanism is arranged in the freezing chamber and close to the air outlet, and the projection of the ice making mechanism on the side wall is staggered with the air outlet; the wind direction adjusting mechanism is arranged in the freezing chamber and on the air outlet and is used for guiding the cold air led in from the air outlet to different ice making areas of the ice making mechanism.

Wherein, wind direction adjustment mechanism includes: and one end of the baffle assembly is connected with the side wall, the other end of the baffle assembly is a free end, and the free end rotates relative to the side wall so as to adjust the included angle between the baffle assembly and the axial direction of the air outlet, thereby adjusting the flow direction of cold air.

The projection of the ice making mechanism on the side wall and the air outlet are distributed along the first direction, and the free end rotates in a plane perpendicular to the first direction relative to the side wall.

The projection of the ice making mechanism on the side wall is positioned below the air outlet.

Wherein, the refrigerator still includes: and a temperature sensing assembly provided on the ice making mechanism for acquiring ice making temperatures of a plurality of ice making areas of the ice making mechanism to cause the wind direction adjusting mechanism to guide cool air introduced from the air outlet to a target ice making area of the ice making mechanism based on the ice making temperatures.

Wherein the baffle assembly comprises a grating or a pendulum blade.

Wherein, the ice maker comprises: an ice making box; an ice bank disposed under the ice making case; the bracket is arranged in the freezing chamber and is connected with the chamber wall of the freezing chamber, and the ice making box and the ice storage box are arranged on the bracket.

Wherein, wind channel mechanism includes: the air duct plate is provided with an air outlet; the fan is arranged in the air duct of the air duct plate and is close to the air outlet; the refrigerator further includes: the refrigerating assembly is arranged in the box body and provides cool air for the air duct.

Wherein, the refrigerator still includes: the driving piece is arranged in the box body and connected with the wind direction adjusting mechanism to provide driving force for the wind direction adjusting mechanism; and the controller is connected with the driving piece to control the driving piece to work.

The refrigerator further comprises a display control mechanism which is connected with the controller and used for acquiring a temperature threshold value and transmitting the temperature threshold value to the controller so that the controller can control the driving piece to work based on the ice making temperature and the temperature threshold value.

The beneficial effects of the utility model are as follows: the refrigerator provided by the utility model comprises: a case; the refrigerator inner container is arranged in the refrigerator body and is internally provided with a freezing chamber; the air duct mechanism is arranged in the box body and positioned between the box body and the refrigerator liner, and the side wall of the freezing chamber is provided with an air outlet which is communicated with the air duct mechanism and the freezing chamber; the ice making mechanism is arranged in the freezing chamber and close to the air outlet, and the projection of the ice making mechanism on the side wall is staggered with the air outlet; the wind direction adjusting mechanism is arranged in the freezing chamber and on the air outlet and is used for guiding the cold air led in from the air outlet to different ice making areas of the ice making mechanism. The ice making mechanism is arranged in the freezing chamber and is close to the air outlet, so that the ice making mechanism can make ice by utilizing the cold air led in from the air outlet; furthermore, the projection of the ice making mechanism on the side wall is staggered with the air outlet, so that cold air can more smoothly flow into the freezing chamber, the cold air quantity is increased, and the whole ice making speed of the ice making mechanism can be improved; further, the wind direction adjusting mechanism is arranged in the freezing chamber and on the air outlet, so that the direction of the cold air can be adjusted by the wind direction adjusting mechanism, and the cold air can be led to different areas of the ice making mechanism, and the ice making uniformity and the ice making speed of the ice making mechanism can be further improved. Therefore, the utility model can effectively improve the ice making uniformity of the refrigerator and can improve the ice making speed of the refrigerator.

Drawings

For a clearer description of the technical solutions of the embodiments of the present utility model, the drawings that are needed in the description of the embodiments will be briefly introduced below, it being obvious that the drawings in the description below are only some embodiments of the present utility model, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art, wherein:

fig. 1 is a schematic view of a refrigerator according to an embodiment of the present utility model;

FIG. 2 is a right side schematic view of the refrigerator of the embodiment of FIG. 1;

fig. 3 is a flow chart illustrating an embodiment of a flow control method of a refrigerator according to the present utility model.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present utility model, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present utility model, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

The utility model firstly proposes a refrigerator, as shown in fig. 1 to 3, fig. 1 is a schematic structural diagram of an embodiment of the refrigerator of the utility model; FIG. 2 is a right side schematic view of the refrigerator of the embodiment of FIG. 1; fig. 3 is a flow chart illustrating an embodiment of a flow control method of a refrigerator according to the present utility model. The refrigerator of the embodiment comprises a refrigerator body 10, a refrigerator liner 19, an air duct mechanism, an ice making mechanism 20 and a wind direction adjusting mechanism, wherein the refrigerator liner 19 is arranged in the refrigerator body 10, and a freezing chamber 11 is arranged in the refrigerator liner 19; the air duct mechanism is arranged in the box body 10 and is positioned between the box body 10 and the refrigerator liner 19, and the side wall of the freezing chamber 11 is provided with an air outlet 12 which is communicated with the air duct mechanism and the freezing chamber 11; the ice making mechanism 20 is arranged in the freezing chamber 11 and is close to the air outlet 12, and the projection of the ice making mechanism 20 on the side wall of the freezing chamber 11 is staggered with the air outlet 12; a wind direction adjusting mechanism is provided in the freezing chamber 11 and on the air outlet 12, the wind direction adjusting mechanism being for guiding cool air introduced from the air outlet 12 to different ice making areas of the ice making mechanism 20.

Specifically, in the present embodiment, the area where the wind direction adjusting mechanism, the air outlet 12, and the ice making mechanism 20 are located is described as being located at the upper left of the refrigerator, and is located at the upper left of the side wall of the freezing chamber 11, however, in other embodiments, the wind direction adjusting mechanism, the air outlet, and the ice making mechanism may be located at the upper right of the refrigerator or at other positions.

Specifically, in the present embodiment, in the rapid ice making mode, the wind direction adjusting mechanism has a wind direction adjusting state and a non-wind direction adjusting state, and when in the wind direction adjusting state, the wind direction adjusting mechanism is adjusted in the wind direction adjusting state, and the wind direction adjusting mechanism can guide the cool air introduced from the air outlet 12 to different ice making areas of the ice making mechanism 20. The switching basis of the two states can be obtained by arranging the detection module, so that the wind direction adjusting mechanism can automatically judge whether the wind direction adjusting mechanism enters the wind direction adjusting state or not in the quick ice making mode.

The above structure of the embodiment has the advantages that the ice making mechanism 20 is arranged in the freezing chamber 11 and is arranged close to the air outlet 12, so that the ice making mechanism 20 can make ice by using the cold air led in from the air outlet 12; further, the projection of the ice making mechanism 20 on the side wall of the freezing chamber 11 is staggered with the air outlet 12, so that cold air can more smoothly flow into the freezing chamber 11, the cold air quantity is increased, and the whole ice making speed of the ice making mechanism 20 can be improved; further, the wind direction adjusting mechanism of the present embodiment is disposed in the freezing chamber 11 and on the air outlet 12, so that the direction of the cool air can be adjusted by the wind direction adjusting mechanism, and the cool air can be led to different areas of the ice making mechanism 20, thereby further improving the ice making uniformity and the ice making speed of the ice making mechanism 20. Therefore, the embodiment can effectively improve the ice making uniformity of the refrigerator and can improve the ice making speed of the refrigerator.

Optionally, in this embodiment, the side wall of the freezing chamber 11 is further provided with other air outlets 12, for example, other air outlets 12 may be further provided at the upper right, lower left, lower right and middle positions of the side wall of the freezing chamber 11, respectively, and the air outlets 12 and other air outlets 12 close to the ice making mechanism 20 may provide uniform cool air for the freezing chamber 11, so as to improve the temperature uniformity of the freezing chamber 11.

Of course, in other embodiments, the number of air outlets is not limited.

Of course, in other embodiments, the position of the air outlet is not limited.

Optionally, the wind direction adjusting mechanism includes a baffle assembly 13, one end of the baffle assembly 13 is connected with a side wall of the freezing chamber 11, and the other end is a free end, and the free end rotates relative to the side wall of the freezing chamber 11 to adjust an included angle between the baffle assembly 13 and an axial direction y of the air outlet 12, thereby adjusting a flow direction of the cold air.

The above structure of the embodiment has the advantages that the baffle plate component 13 of the wind direction adjusting mechanism can adjust the flow direction of the cold air; further, since the free end of the baffle assembly 13 can freely move, multi-angle adjustment of the cold air flowing direction can be realized, and the flexibility of the wind direction adjusting mechanism is improved, so that more cold air can be guided to the ice making area with higher temperature or poor ice making effect of the ice making mechanism 20, and the ice making uniformity of different ice making areas of the ice making mechanism 20 can be improved.

Optionally, the free end of the baffle assembly 13 can adjust the included angle by manual adjustment, and the included angle can be automatically controlled by the controller according to corresponding preset conditions. The combination of multiple control modes can improve the flexibility of the wind direction adjusting mechanism for adjusting the wind direction.

Alternatively, the projection of the ice making mechanism 20 on the side wall of the freezing chamber 11 and the air outlet 12 are arranged along the first direction x, and the free end of the baffle assembly 13 rotates relative to the side wall of the freezing chamber 11 in a plane perpendicular to the first direction x.

For example, the first direction x may be a vertical direction, and the free end of the barrier assembly 13 rotates in a horizontal plane with respect to the sidewall of the freezing chamber 11, i.e., the barrier assembly 13 swings left and right, so that the ice making speed of the left ice making area or the right ice making area of the ice making mechanism 20 can be adjusted, thereby improving the ice making uniformity of all ice making areas of the whole ice making mechanism 20.

The beneficial effects of the structure of this embodiment lie in that, the projection of the ice making mechanism 20 on the side wall of the freezing chamber 11 and the air outlet 12 are arranged along the first direction x, the free end of the baffle assembly 13 rotates in the plane perpendicular to the first direction x relative to the side wall of the freezing chamber 11, so that the ice making mechanism 20, the baffle assembly 13, the ice making mechanism 20 and the air outlet 12 are all not overlapped in the first direction x, the installation and arrangement of the baffle and the ice making mechanism 20 are facilitated, the efficiency and the effect of the baffle assembly 13 in guiding cool air to different refrigerating areas of the ice making mechanism 20 can be improved, and the installation convenience of the assembly is improved.

Alternatively, the projection of the ice making mechanism 20 on the side wall of the freezing chamber 11 is located below the air outlet 12.

The beneficial effects of the structure of the embodiment are that the projection of the ice making mechanism 20 on the side wall of the freezing chamber 11 is located below the air outlet 12, so that the ice making mechanism 20 is located below the baffle assembly 13, the ice making surface of the ice making mechanism 20 is convenient, that is, the opening of the ice making box is upward, and the falling risk of liquid, solid and the like of the ice making mechanism 20 can be improved.

In other embodiments, the projected width of the air outlet on the top wall of the refrigerator is greater than or equal to the projected width of the ice making mechanism 20 on the top wall of the refrigerator. The structure can enable the ice making mechanism to have more ice making areas located in the coverage area of the air outlet, so that the cold air quantity flowing through the ice making mechanism can be increased, the heat exchange efficiency of the ice making mechanism and the cold air of the air outlet can be improved, and the ice making speed of the ice making mechanism can be improved.

Optionally, the refrigerator further includes a temperature sensing assembly provided on the ice making mechanism 20 for acquiring ice making temperatures of a plurality of ice making regions of the ice making mechanism 20 to cause the wind direction adjusting mechanism to guide cool air introduced from the air outlet 12 to a target ice making region of the ice making mechanism 20 based on the ice making temperatures.

The beneficial effect of the structure of the embodiment is that the temperature information of each ice making area of the ice making mechanism 20 can be obtained through the temperature sensing assembly, and the ice making effect can be represented by the temperature information, so that the temperature information of each ice making area is obtained through the temperature sensing assembly, the angle of the baffle assembly 13 is adjusted based on the temperature information, and the control accuracy of the ice making uniformity can be improved.

Of course, in other embodiments, the specific location of the temperature sensing assembly is not limited, and may be positioned, for example, in a different ice making region of the ice making housing or above the ice making housing.

Of course, in other embodiments, the number of the temperature sensing assemblies is not limited, and a plurality of temperature sensing assemblies may be disposed on the top wall of the freezing chamber corresponding to different ice making areas, so that temperatures of the different ice making areas may be provided as references for wind direction adjustment, and accuracy of temperature detection of the ice making box may be improved.

Optionally, the baffle assembly 13 includes a grating or a pendulum.

The beneficial effects of the structure of the embodiment are that the design of the grid element or the swing blade element has small blocking effect on the cold air, so that the flow guiding efficiency of the baffle assembly 13 for guiding the cold air to the ice making mechanism 20 can be improved, and the ice making speed of the ice making mechanism 20 can be further improved.

In other embodiments, the shape of each baffle in the baffle assembly is not limited and may be partially or completely different.

In other embodiments, the dimensions of the various baffles in the baffle assembly are not limited and may be partially or completely different.

In other embodiments, the number of baffles in the baffle assembly is not limited.

In other embodiments, the dimensional length of the baffle assembly extending along the outlet axial direction y is not limited.

In other embodiments, the arrangement density and arrangement range of the baffle assembly along the second direction z are not limited.

Alternatively, the ice making mechanism 20 includes an ice making housing 14, an ice bank 15, and a bracket. The ice bank 15 is disposed under the ice making case 14; the frame is provided in the freezing chamber 11 and connected to the chamber wall of the freezing chamber 11, and the ice-making case 14 and the ice bank 15 are provided on the frame.

The chamber walls of the freezing chamber 11 include top, bottom and side walls of the freezing chamber 11.

The above structure of the embodiment has the advantages that the ice storage box 15 is arranged below the ice making box 14, a user can de-ice the ice making box 14 manually or automatically in a refrigerator, and ice cubes fall into the ice storage box 15 for storage; the ice storage box 15 is arranged below the ice making box 14, so that shielding of the ice making box 14 can be reduced, the amount of cold air led in by the air outlet 12 and cold air for heat exchange with the ice making box 14 can be increased, the heat exchange area of the ice making box 14 and cold air close to the air outlet 12 can be increased, the heat exchange efficiency is improved, and the ice making speed of the ice making mechanism 20 is further increased; and the ice bank 15 is disposed under the ice making case 14 to improve convenience of ice storage at the end of ice making; furthermore, the bracket design can reduce the shielding around the ice making box 14, and increase the heat exchange area of the cold air of the ice making box 14 and the air outlet 12, so as to improve the ice making speed of the ice making box 14 and further improve the ice making speed of the ice making mechanism 20; and the ice making box 14 and the ice storage box 15 are arranged on the bracket, so that the convenience in taking the ice making box 14 and the ice storage box 15 can be improved.

Of course, in other embodiments, the fixing manner of the ice making housing, the ice bank and the refrigerator freezer compartment wall is not limited, and for example, a partition plate may be used instead of a bracket to place the ice bank and the ice making housing.

Optionally, the air duct mechanism includes: the air duct plate 23 and the fan 21. The air duct plate 23 is provided with an air outlet 12; the fan 21 is arranged in the air duct of the air duct plate 23 and is arranged close to the air outlet 12; the refrigerator further includes a cooling assembly 22, and the cooling assembly 22 is disposed in the cabinet 10 to provide cool air to the air duct.

The beneficial effects of the structure of the embodiment are that the refrigeration assembly 22 can provide heat exchange medium for the ice making mechanism 20, so as to ensure the ice making effect of the ice making mechanism 20, and the air duct of the air duct mechanism can guide the cool air generated by the refrigeration assembly 22 to the air outlet 12.

Optionally, the refrigerator further comprises a driving piece and a controller, wherein the driving piece is arranged in the refrigerator body 10 and is connected with the wind direction adjusting mechanism to provide driving force for the wind direction adjusting mechanism; the controller is connected with the driving piece to control the driving piece to work.

The control area is connected with the driving piece and controls the driving piece to work, so that the included angle between the baffle plate assembly 13 and the axial y of the air outlet 12 can be automatically controlled according to the information collected by the temperature sensing assembly, and the flexibility, convenience and response speed of controlling the wind direction adjusting mechanism can be improved.

Optionally, the controller is respectively connected with the driving member, the refrigeration assembly 22, the fan 21 and the temperature sensing assembly to control the driving member, the refrigeration assembly 22, the fan 21 and the temperature sensing assembly to work.

The structure of the embodiment has the beneficial effects that the driving piece is connected with the wind direction adjusting mechanism, so that the control flexibility of the wind direction adjusting mechanism is improved, and the control convenience and the control accuracy of the wind direction adjusting mechanism can be improved; and further, the controller is respectively connected with the driving piece, the refrigerating assembly 22, the fan 21 and the temperature sensing assembly, so that the controller can automatically control the driving piece according to the information collected by the temperature sensing assembly and the preset condition, thereby automatically controlling the wind direction regulating mechanism; therefore, the structure can enable the refrigerator to automatically adjust the included angle between the wind direction adjusting mechanism baffle plate assembly 13 and the axial direction y of the air outlet 12 according to the ice making temperature of the ice making mechanism 20, thereby adjusting the ice making speed and the ice making uniformity of the ice making mechanism 20.

Optionally, the refrigeration assembly 22 includes a compressor, a condenser, an evaporator, and a throttling component, where the compressor is connected to the evaporator and the condenser through pipelines, and the compressor is a power source of the refrigerator and is used to adiabatically compress low-temperature low-pressure refrigerant dry saturated vapor from the evaporator to become high-temperature high-pressure superheated vapor to the condenser; the condenser is also connected with the throttling component and used for condensing the high-temperature high-pressure superheated steam from the compressor under the isobaric condition and radiating heat to a surrounding medium to form high-pressure supercooled liquid; the throttling component is also connected with the evaporator, and the high-pressure supercooled liquid of the throttling component is throttled by the throttling component and then becomes low-temperature low-pressure refrigerant vapor which enters the evaporator to be evaporated; the low-temperature low-pressure refrigerant wet vapor throttled by the throttling component boils in the evaporator under the isobaric condition, absorbs heat of surrounding medium and becomes low-temperature low-pressure refrigerant dry saturated vapor to the compressor.

Further, the controller is respectively connected with the compressor, the condenser and the evaporator and controls the compressor, the condenser and the evaporator to work.

Optionally, the refrigerator of this embodiment further includes a display control mechanism, where the display control mechanism is connected to the controller, and the display control mechanism is used to obtain a temperature threshold and transmit the temperature threshold to the controller, so that the controller controls the driving piece to work based on the ice making temperature and the temperature threshold.

Specifically, in this embodiment, the ice making control process is shown in fig. 3, and the specific steps are as follows:

step S1: the user confirms the entering of the quick ice making function through the display control mechanism.

Step S2: the controller receives a command to make ice quickly.

Step S3: the controller acquires the temperature distribution of the ice making box detected by the temperature sensing assembly.

Step S4: the controller judges whether the temperature of each area of the ice making box is not higher than a preset temperature T. If yes, go to step S5; if not, the process proceeds to step S6.

Step S5: the ice making is completed and the controller ends the fast ice making mode.

Step S6: the controller judges whether the temperature of the left ice making area of the ice making box is equal to the temperature of the right ice making area, if so, the step S7 is carried out; if not, the process proceeds to step S8.

Step S7: the controller does not activate the wind direction adjustment mechanism and proceeds to step S3.

Step S8: the controller judges whether the temperature of the left ice making area of the ice making box is higher than the temperature of the right ice making area, if so, the step S9 is carried out; if not, the process proceeds to step S10.

Step S9: the controller controls the driving member to drive the flap assembly to adjust the wind direction to the left ice making area.

Step S10: the controller controls the driving member to drive the baffle assembly to adjust the wind direction to the right ice making area.

The structure of the embodiment has the advantages that the refrigerator can detect the temperature distribution of the ice making mechanism 20 according to the requirement of a user, and automatically judge whether the baffle plate assembly 13 needs to be adjusted to adjust the wind direction according to the temperature distribution; when the wind direction needs to be adjusted, the position of the baffle plate can be intelligently adjusted according to the temperature distribution, so that the cool air led in by the air outlet 12 is more guided to the ice making area with high temperature, the ice making uniformity of the ice making mechanism 20 can be improved, and the ice making speed of the ice making mechanism 20 can be improved; and further, the display control mechanism can improve the convenience of interaction.

Alternatively, in the present embodiment, the preset temperature T may be adjusted by the user, and the lowest temperature value that T may be set is the lowest temperature of the freezing chamber 11. This setting can improve the convenience of ice-making.

Alternatively, in this embodiment, the temperature sensing assembly may be in a temperature detecting state all the time, and detect the temperature of the object to be detected in the ice making housing 14 in real time.

In other embodiments, besides the controller can be manually controlled through the display control mechanism, the controller can also automatically control the wind direction to adjust according to the temperature distribution of the temperature sensing assembly, so that the ice making uniformity of an ice making area of the ice making mechanism is improved, manual operation can be reduced, and convenience is improved.

Unlike the prior art, the refrigerator provided by the utility model comprises: a case; the refrigerator inner container is arranged in the refrigerator body and is internally provided with a freezing chamber; the air duct mechanism is arranged in the box body and positioned between the box body and the refrigerator liner, and the side wall of the freezing chamber is provided with an air outlet which is communicated with the air duct mechanism and the freezing chamber; the ice making mechanism is arranged in the freezing chamber and close to the air outlet, and the projection of the ice making mechanism on the side wall of the freezing chamber is staggered with the air outlet; the wind direction adjusting mechanism is arranged in the freezing chamber and on the air outlet and is used for guiding the cold air led in from the air outlet to different ice making areas of the ice making mechanism. The ice making mechanism is arranged in the freezing chamber and is close to the air outlet, so that the ice making mechanism can make ice by utilizing the cold air led in from the air outlet; furthermore, the projection of the ice making mechanism on the side wall of the freezing chamber is staggered with the air outlet, so that cold air can more smoothly flow into the freezing chamber, the cold air quantity is increased, and the whole ice making speed of the ice making mechanism can be improved; further, the wind direction adjusting mechanism is arranged in the freezing chamber and on the air outlet, so that the direction of the cold air can be adjusted by the wind direction adjusting mechanism, and the cold air can be led to different areas of the ice making mechanism, and the ice making uniformity and the ice making speed of the ice making mechanism can be further improved. Therefore, the utility model can effectively improve the ice making uniformity of the refrigerator and can improve the ice making speed of the refrigerator.

Further, the utility model can comprise a controller which is respectively connected with the driving piece, the refrigerating component, the fan and the temperature sensing component to control the driving piece, the refrigerating component, the fan and the temperature sensing component to work, and the structural design can enable the controller to automatically control the driving piece according to the information collected by the temperature sensing component and the preset condition, so as to automatically control the wind direction regulating mechanism; therefore, the structure can enable the refrigerator to automatically adjust the included angle between the wind direction adjusting mechanism baffle plate and the axial direction of the air outlet according to the ice making temperature of the ice making mechanism, thereby adjusting the ice making speed and the ice making uniformity of the ice making mechanism.

Further, the utility model can realize the effect of user-defined preset temperature, and can improve the convenience of ice making.

Further, the utility model can comprise a display control mechanism, can realize interaction effect and can improve the convenience of ice making.

The foregoing is only the embodiments of the present utility model, and therefore, the patent scope of the utility model is not limited thereto, and all equivalent structures or equivalent processes using the descriptions of the present utility model and the accompanying drawings, or direct or indirect application in other related technical fields, are included in the scope of the utility model.

Claims (10)

1. A refrigerator, comprising:

a case;

the refrigerator inner container is arranged in the refrigerator body and is provided with a freezing chamber;

the air duct mechanism is arranged in the box body and is positioned between the box body and the refrigerator liner, and an air outlet which is communicated with the air duct mechanism and the freezing chamber is formed in the side wall of the freezing chamber;

the ice making mechanism is arranged in the freezing chamber and is close to the air outlet, and the projection of the ice making mechanism on the side wall is staggered with the air outlet;

the wind direction adjusting mechanism is arranged in the freezing chamber and on the air outlet, and is used for guiding the cold air led in from the air outlet to different ice making areas of the ice making mechanism.

2. The refrigerator of claim 1, wherein the wind direction adjusting mechanism comprises:

and one end of the baffle assembly is connected with the side wall, the other end of the baffle assembly is a free end, and the free end rotates relative to the side wall so as to adjust an included angle between the baffle assembly and the axial direction of the air outlet, thereby adjusting the flow direction of the cold air.

3. The refrigerator of claim 2, wherein the projection of the ice making mechanism on the side wall is arranged along a first direction with the air outlet, and the free end rotates relative to the side wall in a plane perpendicular to the first direction.

4. The refrigerator of claim 3, wherein a projection of the ice making mechanism on the side wall is located below the air outlet.

5. The refrigerator of claim 1, further comprising:

and the temperature sensing assembly is arranged on the ice making mechanism and is used for acquiring ice making temperatures of a plurality of ice making areas of the ice making mechanism so that the air direction adjusting mechanism guides the cold air introduced from the air outlet to a target ice making area of the ice making mechanism based on the ice making temperatures.

6. The refrigerator of claim 2, wherein the baffle assembly comprises a grating or a swing blade.

7. The refrigerator of claim 1, wherein the ice making mechanism comprises:

an ice making box;

an ice bank disposed under the ice making case;

the bracket is arranged in the freezing chamber and is connected with the cavity wall of the freezing chamber, and the ice making box and the ice storage box are arranged on the bracket.

8. The refrigerator of claim 7, wherein the air duct mechanism comprises:

the air duct plate is provided with the air outlet;

the fan is arranged in the air duct of the air duct plate and is close to the air outlet;

the refrigerator further includes:

and the refrigerating assembly is arranged in the box body and provides the cold air for the air duct.

9. The refrigerator of claim 8, further comprising:

the driving piece is arranged in the box body, is connected with the wind direction adjusting mechanism and provides driving force for the wind direction adjusting mechanism;

and the controller is connected with the driving piece to control the driving piece to work.

10. The refrigerator of claim 9, further comprising a display control mechanism connected to the controller, wherein the display control mechanism is configured to obtain a temperature threshold and transmit the temperature threshold to the controller, so that the controller controls the driving member to operate based on the ice making temperature and the temperature threshold.