CN112325526A

CN112325526A - Ice maker and refrigerator

Info

Publication number: CN112325526A
Application number: CN201910702335.0A
Authority: CN
Inventors: 施恩
Original assignee: Suzhou Samsung Electronics Co Ltd; Samsung Electronics Co Ltd
Current assignee: Suzhou Samsung Electronics Co Ltd; Samsung Electronics Co Ltd
Priority date: 2019-07-31
Filing date: 2019-07-31
Publication date: 2021-02-05
Anticipated expiration: 2039-07-31
Also published as: CN112325526B

Abstract

The invention discloses an ice maker and a refrigerator, wherein a controller of the ice maker controls a driving assembly to drive a connecting shaft rod to rotate in a second direction until an ice making push rod completely closes a second opening; controlling the water supply assembly to supply water to the ice making groove for a first preset time; the ice making is carried out for a second preset time, and the ice making is finished; the controller controls the ice moving heating assembly to operate for a third preset time, and controls the driving assembly to drive the connecting shaft rod to rotate in the first direction until the ice moving push rod pushes the ice blocks out of the second opening. The ice maker can realize the action switching of the ice moving push rod and the ice making push rod through one connecting shaft rod, and the connecting shaft rod only needs to be driven by the driving assembly, so that the structure is relatively simple compared with the prior art.

Description

Ice maker and refrigerator

Technical Field

The invention relates to the technical field of ice making of refrigerators, in particular to an ice making machine and a refrigerator.

Background

Along with the increasing living standard of people, people have more and more demand for ice cubes in daily life, and therefore, the automatic ice maker is suitable for transportation. However, the conventional automatic ice maker has relatively complex and inconvenient maintenance due to the application of various gear reduction structures.

Therefore, how to simplify the structure of the ice maker is a problem to be solved urgently by those skilled in the art.

Disclosure of Invention

In view of this, the technical problem to be solved by the present invention is how to simplify the structure of the ice maker, and therefore, the present invention provides an ice maker and a refrigerator.

In order to achieve the purpose, the invention provides the following technical scheme:

an ice making machine comprising:

the ice making device comprises an ice making groove for making ice, wherein an ice making cavity for making ice is formed in the ice making groove, the top of the ice making groove is provided with a first opening communicated with the ice making cavity, and the bottom of the ice making groove is provided with a second opening communicated with the ice making cavity;

an ice moving push rod capable of pushing ice cubes out of the second opening through the first opening;

an ice making push rod capable of sealing the second opening;

a connecting shaft rod connecting the ice moving push rod and the ice making push rod, wherein the connecting shaft rod is connected to a fixed foundation, when the connecting shaft rod rotates in a first direction, the ice moving push rod is close to the first opening, and the ice making push rod is far away from the second opening; when the connecting shaft rod rotates in a second direction, the ice moving push rod is far away from the first opening, and the ice making push rod is close to the second opening;

the driving component drives the connecting shaft rod to rotate;

the water supply assembly is used for supplying water to the ice receiving groove;

the ice moving heating assembly is used for heating the ice making cavity;

the ice receiving groove is used for receiving ice blocks pushed out of the second opening;

the ice detection sensor is used for detecting whether the ice receiving groove is full of ice or not, and an ice making signal is generated if the ice receiving groove is not full of ice; and

the controller controls the driving assembly to drive the connecting shaft rod to rotate in the second direction until the ice making push rod completely closes the second opening when receiving an ice making signal; controlling the water supply assembly to supply water to the ice making groove for a first preset time; the ice making is carried out for a second preset time, and the ice making is finished; the controller controls the ice moving heating assembly to operate for a third preset time, and controls the driving assembly to drive the connecting shaft rod to rotate in the first direction until the ice moving push rod pushes the ice blocks out of the second opening.

In one embodiment of the invention, the connecting rod is in a circular arc structure, and the connecting rod is connected to the fixed foundation through a connecting rod; the ice moving push rod is arranged at one end of the connecting shaft rod, and the ice making push rod is arranged at the other end of the connecting shaft rod;

the driving component is a speed reduction direct current motor, an output shaft of the speed reduction direct current motor is provided with a driving wheel, and the driving wheel is matched with the connecting shaft rod and drives the connecting shaft rod to rotate in the first direction and the second direction.

In one embodiment of the invention, the transmission wheel is a transmission gear, and a transmission tooth meshed with the transmission gear is arranged at a position corresponding to the connecting shaft rod.

In one embodiment of the present invention, a sealing rubber layer is disposed at a portion where the ice making push rod is engaged with the second opening.

In one embodiment of the present invention, there are a plurality of ice making cavities, and each ice making cavity has one first opening and one second opening.

In one embodiment of the invention, the ice moving push rod comprises an ice moving support plate and a plurality of ice moving push rods arranged on the ice moving support plate, and each ice moving push rod corresponds to one ice making cavity.

In one embodiment of the present invention, the ice-detecting sensor is an infrared detector.

In one embodiment of the invention, a temperature sensor is arranged on one side of the ice making push rod corresponding to the ice making cavity, and when the internal temperature of the ice making cavity reaches a first preset temperature, the controller controls the water supply assembly to stop supplying water; and when the internal temperature of the ice making cavity reaches a second preset temperature, ice making is finished.

In one embodiment of the invention, the water supply assembly comprises a control valve and a water inlet pipe, the water inlet pipe is connected with the control valve and a water source, and when the controller receives an ice making signal and the ice making push rod completely closes the second opening, the controller controls the control valve to be conducted; when the internal temperature of the ice making cavity reaches a first preset temperature, the controller controls the control valve to be non-conductive.

The invention also discloses a refrigerator comprising the ice maker.

According to the technical scheme, the controller of the ice maker controls the driving assembly to drive the connecting shaft rod to rotate in the second direction until the ice making push rod completely closes the second opening; controlling the water supply assembly to supply water to the ice making groove for a first preset time; the ice making is carried out for a second preset time, and the ice making is finished; the controller controls the ice moving heating assembly to operate for a third preset time, and controls the driving assembly to drive the connecting shaft rod to rotate in the first direction until the ice moving push rod pushes the ice blocks out of the second opening. The ice maker can realize the action switching of the ice moving push rod and the ice making push rod through one connecting shaft rod, and the connecting shaft rod only needs to be driven by the driving assembly, so that the structure is relatively simple compared with the prior art.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

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

In the figure, 100 is an ice making groove, 101 is an ice making cavity, 102 is a first opening, 103 is a second opening, 200 is an ice moving push rod, 201 is an ice moving support plate, 202 is an ice moving push rod, 300 is an ice making push rod, 301 is an ice making support plate, 302 is an ice making blocking rod, 303 is a sealing rubber layer, 304 is a temperature sensor, 400 is a connecting rod, 401 is a connecting rod, 500 is a driving component, 600 is a water supply component, 601 is a water inlet pipe, 602 is a control valve, 603 is a water pump, 604 is a water tank, 700 is an ice moving heating component, 800 is an ice receiving groove, 801 is an ice detecting sensor, and 900 is a controller.

Detailed Description

The core of the invention is to provide an ice maker and a refrigerator so as to simplify the structure of the ice maker.

The embodiments described below do not limit the contents of the invention described in the claims. The entire contents of the configurations shown in the following embodiments are not limited to those required as solutions of the inventions described in the claims.

Referring to fig. 1, an ice maker according to an embodiment of the present invention includes:

the ice making device comprises an ice making groove 100 for making ice, an ice making cavity 101 for making ice is formed in the ice making groove 100, the top of the ice making groove 100 is provided with a first opening 102 communicated with the ice making cavity 101, and the bottom of the ice making groove 100 is provided with a second opening 103 communicated with the ice making cavity 101;

an ice moving push rod 200 capable of pushing ice cubes out of the second opening 103 through the first opening 102;

an ice making push rod 300 capable of sealing the second opening 103;

a connecting rod 400 connecting the ice moving push rod 200 and the ice making push rod 300, the connecting rod 400 being coupled to a fixed base, when the connecting rod 400 rotates in a first direction a, the ice moving push rod 200 approaches the first opening 102, and the ice making push rod 300 is away from the second opening 103; when the connecting shaft rod 400 rotates in the second direction b, the ice moving push rod 200 is away from the first opening 102, and the ice making push rod 300 is close to the second opening 103;

a driving assembly 500 for driving the coupling rod 400 to rotate;

a water supply assembly 600 for supplying water to the ice receiving groove 800;

an ice moving heating assembly 700 for heating the ice making chamber 101;

an ice receiving groove 800 for receiving ice cubes pushed out of the second opening 103;

an ice detecting sensor 801 for detecting whether the ice receiving groove 800 is full of ice, and generating an ice making signal if the ice receiving groove is not full of ice; and

the controller 900, when receiving the ice making signal, the controller 900 controls the driving assembly 500 to drive the connecting shaft rod 400 to rotate in the second direction b until the ice making push rod 300 completely closes the second opening 103; controlling the water supply assembly 600 to supply water to the ice making groove 100 for a first preset time; the ice making is carried out for a second preset time, and the ice making is finished; the controller 900 controls the ice-moving heating assembly 700 to operate for a third preset time, and controls the driving assembly 500 to drive the connecting rod 400 to rotate in the first direction a until the ice-moving push rod 200 pushes the ice cubes out of the second opening 103.

The ice maker of the present invention can switch the actions of the ice moving push rod 200 and the ice making push rod 300 through one connecting rod 400, and the connecting rod 400 only needs to be driven by the driving assembly 500, so that the structure is relatively simple compared to the prior art.

It should be noted that the connecting shaft rod 400 is operatively connected to the ice making push rod 300 and the ice moving push rod 200, and the rotation direction of the connecting shaft rod 400 is changed to switch whether the ice making push rod 300 and the ice moving push rod 200 are close to or far away from the ice making groove 100, so as to switch to close the ice making groove 100 and push the ice cubes.

Preferably, the connecting shaft rod 400 of the present invention has a curved structure, and one end is close to the ice making groove 100 and the other end is far from the ice making groove 100 by rotating in the first direction a; one end is moved away from the ice making groove 100 and the other end is moved close to the ice making groove 100 by rotating in the second direction b. Preferably, the connecting rod 400 is in a circular arc structure, and the connecting rod 400 is coupled to the fixed foundation through a connecting rod 401; the ice moving push rod 200 is arranged at one end of the connecting shaft rod 400, the ice making push rod 300 is arranged at the other end of the connecting shaft rod 400, the processing of the connecting shaft rod 400 is facilitated by arranging a circular arc-shaped structure, and the precision is easier to ensure. In the embodiment of the invention, the first direction a and the second direction b are opposite.

It should be noted that the function of the connecting rod 401 is to realize the axial connection of the connecting rod 400 with respect to the fixed base, and the connecting rod 401 may be understood as a separate rod-shaped structure, and may also be a plate-shaped structure, as long as the function of the connecting rod 400 being axially connected to the fixed base is achieved, and all that is within the protection scope of the present invention.

And a fixed base, which may be understood herein as a portion of the structure of the refrigerator to support the rotation of the link shaft 400 in the first direction a and the second direction b, or may be separately used as a portion of the self-generating structure of the ice maker, by which the fixation of the ice maker with respect to the refrigerator can be accomplished when it is required to be installed on the refrigerator.

The corresponding driving assembly 500 is a deceleration dc motor, and an output shaft of the deceleration dc motor is provided with a driving wheel, which is engaged with the connecting rod 400 and drives the connecting rod 400 to rotate in the first direction a and the second direction b. The use of more speed reduction transmission parts can be saved by adopting the speed reduction direct current motor, and the structure is further simplified.

The transmission between the transmission wheel and the connecting shaft rod 400 can be friction transmission; or inter-tooth transmission, specifically, the transmission wheel is a transmission gear, and the corresponding position of the connecting shaft rod 400 is provided with transmission teeth meshed with the transmission gear. Wherein, the transmission gear may be disposed at the inner side of the connecting rod 400 and also disposed at the outer side of the connecting rod 400. The transmission gear is arranged at the inner side of the connecting shaft rod 400, so that the space occupied by the whole ice maker can be further reduced. The driving gear is disposed at the outer side of the connecting shaft rod 400, so that the connecting shaft rod 400 is easier to process.

In order to ensure the sealing performance of the ice making cavity 101 during the ice making process, a sealing rubber layer 303 is arranged at the part of the ice making push rod 300 matched with the second opening 103.

In order to improve the ice making efficiency of the ice making machine, in one embodiment of the invention, a plurality of ice making cavities 101 are provided, and each ice making cavity 101 is provided with a first opening 102 and a second opening 103. Each ice making chamber 101 enables the production of one ice cube. Therefore, when a plurality of ice making cavities 101 are provided, the manufacture of a plurality of ice cubes can be completed. The cross section of ice making chamber 101 is in a regular shape such as a circle, a square, or a rectangle.

The ice moving push rod 200 comprises an ice moving support plate 201 and a plurality of ice moving push rods 202 arranged on the ice moving support plate 201, wherein each ice moving push rod 202 corresponds to one ice making cavity 101. After the ice moving heating assembly 700 heats the ice making cavity 101, the ice cubes are melted around, and when the ice moving support plate 201 moves downwards, the corresponding ice moving push rods 202 can push the ice cubes in the ice making cavity 101 downwards and push the ice cubes out through the second opening 103.

The ice receiving groove 800 may be located right below the second opening 103 for the purpose of receiving ice. The transfer of the ice pieces ejected from the second opening 103 into the ice receiving chute 800 can of course also be achieved by a transfer structure. It is within the scope of the present invention to accomplish the function of receiving ice.

The ice making push lever 300 includes an ice making support plate 301, and a plurality of ice making blocking levers 302 provided on the ice making support plate 301, each ice making blocking lever 302 having one second opening 103. Wherein a sealing rubber layer 303 may be provided on the ice making support plate 301 to integrally close all the second openings 103, and a sealing rubber layer 303 may be further provided on each ice making blocking lever 302 to individually close the corresponding second opening 103. Or each ice making blocking rod 302 and the ice making supporting plate 301 are provided with a sealing rubber layer 303 to achieve the double sealing effect.

In one embodiment of the present invention, the ice detecting sensor 801 is an infrared detector for detecting whether the ice receiving tank 800 is full of ice by infrared rays. The infrared detector comprises an infrared emitter and an infrared receiver which are respectively arranged at the opposite sides of the ice receiving groove 800, and when ice cubes in the ice receiving groove 800 are full of ice, the infrared receiver cannot receive infrared rays emitted by the infrared emitter; when the ice receiving groove 800 is not full of ice, the infrared receiver receives infrared rays emitted from the infrared emitter to generate an ice making signal, and the ice making signal is fed back to the controller 900. The controller 900 performs a corresponding series of operations according to the ice making signal.

The control of the first preset time, the second preset time and the third preset time can be controlled by setting a timer. The controller 900 stores the corresponding relationship between the corresponding first preset time, second preset time and third preset time and the corresponding parameters of the water supply assembly 600 and the ice-moving heating assembly 700 in advance.

Or, the present invention is regulated by setting the temperature sensor 304, specifically, the temperature sensor 304 is arranged at one side of the ice making push rod 300 corresponding to the ice making cavity 101, and when the internal temperature of the ice making cavity 101 reaches a first preset temperature, the controller 900 controls the water supply assembly 600 to stop supplying water; when the internal temperature of the ice making chamber 101 reaches the second preset temperature, ice making is completed.

The water supply assembly 600 is used for supplying water into the ice making groove 100, the embodiment of the invention specifically discloses a structural form, the water supply assembly 600 comprises a control valve 602 and a water inlet pipe 601, the water inlet pipe 601 is connected with the control valve 602 and a water source, when the controller 900 receives an ice making signal and the ice making push rod 300 completely closes the second opening 103, the controller 900 controls the control valve 602 to be conducted; when the internal temperature of ice making chamber 101 reaches a first preset temperature, controller 900 controls control valve 602 to be non-conductive. In the water supply assembly 600 with the structure, the water inlet pipe 601 is directly connected with a water source, the water source can be understood as a domestic water source, and the domestic water source is provided with pressure, so that water supply and non-water supply of the water supply assembly 600 can be realized by controlling the conduction and non-conduction of the control valve 602.

Further, the water supply assembly 600 further includes a water tank 604 and a water pump 603, wherein the water tank 604 is used as a water source of the above embodiment, a part of the water source is separately stored, the water pump 603 is communicated with the water inlet pipe 601, and the controller 900 realizes water supply and non-water supply of the water supply assembly 600 by simultaneously controlling the water pump 603 and the control valve 602.

The invention also discloses a refrigerator comprising the ice maker. Since the ice maker has the beneficial effects, the refrigerator comprising the ice maker also has corresponding technical effects, and the details are not repeated herein.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. An ice maker, comprising:

an ice making push rod capable of sealing the second opening;

the driving component drives the connecting shaft rod to rotate;

the ice moving heating assembly is used for heating the ice making cavity;

2. The ice-making machine of claim 1, wherein said connecting rod is in the form of a circular arc, said connecting rod being pivotally connected to said stationary base by a connecting rod; the ice moving push rod is arranged at one end of the connecting shaft rod, and the ice making push rod is arranged at the other end of the connecting shaft rod;

3. The ice-making machine of claim 2, wherein said transmission wheel is a transmission gear, and a corresponding position of said connecting shaft is provided with a transmission tooth engaged with said transmission gear.

4. The ice-making machine of claim 1, wherein a sealing rubber layer is disposed at a portion where said ice-making push rod is engaged with said second opening.

5. The ice-making machine of claim 1, wherein said ice-making chamber is plural, and wherein each said ice-making chamber has one said first opening and one said second opening.

6. The ice-making machine of claim 5, wherein said ice-moving push rod comprises an ice-moving support plate and a plurality of ice-moving push rods disposed on said ice-moving support plate, each of said ice-moving push rods corresponding to one of said ice-making cavities.

7. The ice-making machine of claim 1, wherein said ice-detecting sensor is an infrared detector.

8. The ice-making machine of claim 1, wherein a side of the ice-making push rod corresponding to the ice-making cavity is provided with a temperature sensor, and the controller controls the water supply assembly to stop supplying water when the internal temperature of the ice-making cavity reaches a first preset temperature; and when the internal temperature of the ice making cavity reaches a second preset temperature, ice making is finished.

9. The ice-making machine of claim 8, wherein said water supply assembly includes a control valve and a water inlet pipe, said water inlet pipe connecting said control valve and a water source, said controller controlling said control valve to conduct when said controller receives an ice-making signal and said ice-making push rod completely closes said second opening; when the internal temperature of the ice making cavity reaches a first preset temperature, the controller controls the control valve to be non-conductive.

10. A refrigerator characterized by comprising the ice maker as claimed in any one of claims 1 to 9.