WO2024046387A1 - Refrigerating and freezing device - Google Patents

Abstract

A refrigerating and freezing device (10), comprising: a box body (100), the interior of which defines a first storage area (650) and a second storage area (680); and a rotating storage box (900), which is provided with a plurality of storage compartments (910), each of the storage compartments (910) defining a storage partition, wherein the rotating storage box (900) is rotatably arranged such that the storage compartments (910) are switchably arranged in the first storage area (650) and the second storage area (680). When it is necessary to switch a certain storage compartment (910) from the first storage area (650) to the second storage area (680), it only needs to rotate the storage compartment (910) from the first storage area (650) to the second storage area (680), and the whole process can be switched to the storage environment of an article without removing the storage compartment (910).

Description

Refrigeration and freezing equipment Technical field

The present invention relates to controlled atmosphere preservation technology, and in particular to a refrigeration and freezing device.

Background technique

Refrigeration and freezing devices with different functional partitions are widely favored by consumers. Since different functional partitions have different fresh-keeping atmospheres, different functional partitions can be used to store different items.

The inventor realized that in the existing refrigeration and freezing devices, items cannot be directly exchanged between different functional partitions. When items need to be moved from one functional partition to another, the user needs to first move the items from the original function partition. The operation process is very complicated when taking it out from one partition and then putting it into another functional partition.

The above information disclosed in this Background Art is only for increasing understanding of the Background Art of this application and, therefore, it may contain prior art that does not constitute prior art known to a person of ordinary skill in the art.

Contents of the invention

An object of the present invention is to overcome at least one technical defect in the prior art and provide a refrigeration and freezing device.

A further object of the present invention is to provide a refrigeration and freezing device that can directly exchange items between different functional partitions, so as to flexibly and skillfully switch the storage environment of items.

Another further object of the present invention is to enable different storage partitions of the refrigeration and freezing device to be switched back and forth between high-oxygen fresh-keeping areas and non-high-oxygen fresh-keeping areas.

In particular, the present invention provides a refrigeration and freezing device, including:

A box whose interior defines a first storage area and a second storage area; and

Rotating storage box, which has a plurality of storage compartments, each storage compartment defines a storage partition; and the rotating storage box is rotatably arranged, so that the storage compartments are switchably arranged at The first storage area and the second storage area.

Optionally, the refrigeration and freezing device also includes:

A storage container is provided in the box; and

A separation mechanism is provided in the internal space of the storage container, and separates the internal space of the storage container into the first storage area and the second storage area; and the separation mechanism is provided with a The rotary storage box is rotatably assembled with an assembly area therein.

Optionally, the partition mechanism is a partition structure with a board surface extending in the vertical direction, so that the first storage area and the second storage area are arranged side by side in the horizontal direction; and

The rotating storage box is cylindrical, with a rotation axis extending in a vertical direction, and the rotation axis of the rotating storage box is coaxial with the central axis of the rotating storage box and the central axis of the assembly area.

Optionally, the partition mechanism includes a first partition section and a second partition section that are spaced apart from each other and whose plates are arranged coplanarly. plate section; and the spacing between the first baffle section and the second baffle section forms the assembly area.

Optionally, the rotating storage box includes a disc-shaped chassis and a hollow cylindrical body extending upward from an edge of the chassis: and

A plurality of storage compartments are formed in the barrel, and the projections of the storage compartments in a horizontal plane are centrally symmetrical with respect to the center of the chassis.

Optionally, the rotating storage box also includes:

a central rotating shaft extending upward from the center of the chassis; and

A plurality of partition plates, the plate surface of each partition plate extends in the vertical direction, and extends radially outward from the outer surface of the central rotating shaft to the inner surface of the cylinder, so as to A plurality of storage compartments with top openings are spaced inside; and one storage partition is defined between every two adjacent partition boards.

Optionally, the first storage area has a vent for introducing external air to adjust the internal atmosphere using the external air; and

Each storage compartment is provided with a ventilation opening to allow the external air to enter the storage partition through the ventilation opening when switching to the first storage area.

Optionally, the first storage area is provided on the rear side of the second storage area; the storage container is pullably provided in the box; the back wall of the storage container is provided with The vent connected to the first storage area; and

The refrigeration and freezing device further includes a gas circuit assembly, which has a ventilation pipeline connected to the ventilation port and used to transport gas to the first storage area, and the ventilation pipeline is fixed to the rear of the storage container. side; and the ventilation pipe and the ventilation port are nested with each other and detachably arranged during the pulling process of the storage container.

Optionally, the vent is in the shape of a hollow column and protrudes outward from the back wall of the storage container; one end of the vent pipe has a hollow cylindrical interface for the vent to be nested therein.

Optionally, the refrigeration and freezing device also includes:

An oxygen treatment device is arranged in the box and has a shell and an electrode pair. The interior of the shell defines an electrochemical reaction chamber for containing electrolyte. The electrode pair is arranged in the electrochemical reaction chamber. The chamber is used to transfer external oxygen to the electrochemical reaction chamber through electrochemical reaction; the housing is provided with an exhaust hole connected to the electrochemical reaction chamber, and is used to discharge oxygen from the electrochemical reaction chamber. ;as well as

The first end of the air conditioning pipeline is used to communicate with the ventilation pipeline, and the second end is used to communicate with the exhaust hole.

In the refrigeration and freezing device of the present invention, a rotating storage box having a plurality of storage compartments is provided in the box body, and the rotating storage box is rotatably arranged, so that the storage compartments are switchably arranged on the first storage compartment. storage area and the second storage area. When a certain storage compartment needs to be switched from the first storage area to the second storage area, it is only necessary to rotate the storage compartment from the first storage area to the second storage area. In the second storage area, there is no need to take out the storage compartment during the entire process. Therefore, using the above solution of the present invention, items can be directly exchanged between different functional partitions to flexibly and skillfully switch the storage environment of items.

Furthermore, the refrigeration and freezing device of the present invention, when using a controlled atmosphere pipeline to transport oxygen from the electrochemical reaction chamber to the first storage area, can create a high-oxygen fresh-keeping environment in the first storage area. When the object compartment is switched from the first storage area to the second storage area, the storage compartment can be switched from the high oxygen preservation area to the non-high oxygen preservation area. When a storage compartment is switched from the second storage area to the first storage area, the storage compartment can be switched from a non-hyperoxygen fresh-keeping area to a high-oxygen fresh-keeping area. Therefore, using the above solution of the present invention, different storage areas of the refrigeration and freezing device can be switched. The object partition can be switched back and forth between the high-oxygen fresh-keeping area and the non-high-oxygen fresh-keeping area.

From the following detailed description of specific embodiments of the present invention in conjunction with the accompanying drawings, those skilled in the art will further understand the above and other objects, advantages and features of the present invention.

Description of drawings

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

Figure 1 is a schematic structural diagram of a refrigeration and freezing device according to an embodiment of the present invention;

Figure 2 is a schematic internal structure diagram of a refrigeration and freezing device according to an embodiment of the present invention;

Figure 3 is a schematic exploded view of the internal structure of the refrigeration and freezing device shown in Figure 2;

Figure 4 is another schematic exploded view of the internal structure of the refrigeration and freezing device shown in Figure 2;

Figure 5 is a schematic structural diagram of the transfer pipeline of the refrigeration and freezing device shown in Figure 4;

Figure 6 is a schematic perspective view of the transfer pipeline of the refrigeration and freezing device shown in Figure 4;

Figure 7 is a schematic structural diagram of an oxygen treatment device of a refrigeration and freezing device according to one embodiment of the present invention;

Figure 8 is a schematic exploded view of the oxygen treatment device of the refrigeration and freezing device shown in Figure 7;

Figure 9 is a schematic structural diagram of a refrigeration and freezing device according to an embodiment of the present invention;

Figure 10 is a schematic internal structure diagram of the refrigeration and freezing device shown in Figure 9;

Figure 11 is a schematic structural diagram of the inner tank of the refrigeration and freezing device according to one embodiment of the present invention;

Figure 12 is a schematic structural diagram of the liquid storage module of the refrigeration and freezing device shown in Figure 10;

FIG. 13 is a schematic perspective view of the liquid storage module of the refrigeration and freezing device shown in FIG. 12 .

Detailed ways

Reference will now be made in detail to the embodiments of the invention, one or more examples of which are illustrated in the accompanying drawings. The various examples are provided to illustrate the invention, but not to limit the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope or spirit of the invention. For example, features illustrated or described as part of one embodiment can be used with another embodiment to produce still further embodiments. Thus, it is intended that the present invention cover such modifications and variations within the scope of the appended claims and their equivalents.

The refrigeration and freezing device 10 according to the embodiment of the present invention will be described below with reference to FIGS. 1 to 13 . Among them, the directions or positional relationships indicated by "inside", "outside", "up", "down", "top", "bottom", "horizontal", "horizontal", "vertical", etc. are based on the directions or positional relationships shown in the drawings, and only It is intended to facilitate the description of the present invention and simplify the description, but does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore cannot be construed as a limitation of the present invention. In order to facilitate illustrating the structure of the device, some of the drawings of the present invention are illustrated in perspective form.

In the description of this embodiment, the terms "first", "second", etc. are only used for descriptive purposes and cannot be understood as indicating or implying relative importance or implicitly indicating the number of indicated technical features. Therefore, features defined as “first”, “second”, etc. may explicitly or implicitly include at least one of the features, that is, include one or more of the features. It should be understood that the term "plurality" means at least two, such as two, three, etc. Unless otherwise expressly and specifically limited. When a feature "includes or includes" one or some of the features it encompasses, unless specifically described otherwise, this indicates that other features are not excluded and may further be included.

In the description of this embodiment, reference to the description of the terms "one embodiment," "some embodiments," "example," "an example," etc., means that a specific feature, structure, material, or material is described in connection with the embodiment or example. Features are included in at least one embodiment or example of the invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

An embodiment of the present invention provides a refrigeration and freezing device 10. Figure 1 is a schematic structural diagram of a refrigeration and freezing device 10 according to an embodiment of the present invention. Figure 2 is a schematic internal structure diagram of the refrigeration and freezing device 10 according to one embodiment of the present invention. The refrigeration and freezing device 10 may generally include a box body 100 and a rotating storage box 900 . The refrigeration and freezing device 10 in the embodiment of the present invention may be a refrigerator, or a refrigeration equipment with a low-temperature storage function such as a refrigerator, a freezer, or a refrigerator.

The interior of the box 100 defines a first storage area 650 and a second storage area 680 . For example, the box 100 may include an inner bladder, and the inner side of the inner bladder may define a storage compartment. The first storage area 650 and the second storage area 680 may be respectively formed in the storage room. For another example, a storage container 600 may be provided in the storage room, and the first storage area 650 and the second storage area 680 may be formed in the storage container 600 .

The rotating storage box 900 has a plurality of storage compartments 910 . FIG. 3 is a schematic exploded view of the internal structure of the refrigeration and freezing device 10 shown in FIG. 2 . Each storage compartment 910 is used to store items respectively. Each storage compartment 910 defines a storage partition, and the storage partition is used to store items. And the rotating storage box 900 is rotatably arranged, so that the storage compartment 910 is switchably arranged in the first storage area 650 and the second storage area 680 .

When the rotary storage box 900 rotates, the position of each storage compartment 910 changes accordingly. For example, it can rotate from the first storage area 650 to the second storage area 680, or from the second storage area 680 to the third storage area. 650 for one storage area. Therefore, each storage compartment 910 can be flexibly switched between the first storage area 650 and the second storage area 680 . It should be noted that, in one example, in addition to the first storage area 650 and the second storage area 680, the interior of the box 100 may also define more storage areas, such as a third storage area and / Or a fourth storage area, etc., when the rotating storage box 900 is rotated, it can be rotated from one storage area to another storage area.

By arranging a rotating storage box 900 with a plurality of storage compartments 910 in the box 100 and allowing the rotating storage box 900 to be rotatably arranged, the storage compartments 910 are switchably arranged in the first storage area 650 and the second storage area 680. When a certain storage compartment 910 needs to be switched from the first storage area 650 to the second storage area 680, the storage compartment 910 only needs to be rotated from the first storage area 650. To the second storage area 680, there is no need to take out the storage compartment 910 during the entire process. Therefore, using the above solution of the present invention, items can be directly exchanged between different functional partitions to flexibly and skillfully switch the storage environment of items.

In some optional embodiments, the refrigeration and freezing device 10 further includes a storage container 600 and a partitioning mechanism 620 . Among them, the storage container 600 is provided in the box 100 . The partition mechanism 620 is disposed in the internal space of the storage container 600 and separates the internal space of the storage container 600 into a first storage area 650 and a second storage area 680 . And the partition mechanism 620 has an assembly area for the rotary storage box 900 to be rotatably assembled therein.

When the rotating storage box 900 is rotatably assembled in the assembly area, the rotating storage box 900 also closes the assembly area, so that the first storage area 650 and the second storage area 680 are not connected to each other.

By dividing the first storage area 650 and the second storage area 680 in the storage container 600 and rotating the rotating storage box 900 to switch the position of any storage compartment 910, it is possible to create a space in the same storage container 600. Multiple different storage atmospheres, and the storage container 600 has a storage function with adjustable storage atmosphere.

In one example, the partition mechanism 620 is a partition structure with a board surface extending in the vertical direction, so that the first storage area 650 and the second storage area 680 are arranged side by side in the horizontal direction. Therefore, each storage compartment 910 of the rotary storage box 900 does not need to change the height when switching positions, which is beneficial to reducing the difficulty of operating each storage compartment 910 when switching positions.

The rotating storage box 900 may be cylindrical, with a rotation axis extending in a vertical direction, and the rotation axis of the rotating storage box 900 is coaxial with the central axis of the rotating storage box 900 and the central axis of the assembly area.

With the above structure, when the rotating storage box 900 rotates, the outline of the rotating storage box 900 remains consistent. Therefore, the rotating storage box 900 always closes the assembly area when rotating, and does not destroy the isolation state between the first storage area 650 and the second storage area 680 .

The partitioning mechanism 620 includes a first partition section 621 and a second partition section 622 which are spaced apart from each other and whose plates are arranged coplanarly. The space between the first partition section 621 and the second partition section 622 forms an assembly area. In one example, the height of the rotating storage box 900 is the same as the height of the first partition section 621 and the height of the second partition section 622 . The rotating storage box 900, the first partition section 621 and the second partition section 622 can respectively extend from the lower surface of the top wall of the storage container 600 to the upper surface of the bottom wall of the storage container 600 to separate the first storage box. The storage area 650 and the second storage area 680 are connected to each other, so that the first storage area 650 and the second storage area 680 are not connected to each other.

In a further example, the rotating storage box 900 includes a disc-shaped chassis and a hollow cylindrical barrel 930 extending upward from an edge of the chassis, thereby defining the hollow cylindrical rotating storage box 900 .

A plurality of storage compartments 910 are formed in the cylinder 930, and the projections of the plurality of storage compartments 910 in a horizontal plane are centrally symmetrical with respect to the center of the chassis.

By arranging multiple storage compartments 910 in the cylinder 930 and making the projection of the multiple storage compartments 910 in the horizontal plane centrally symmetrical with respect to the center of the chassis, the multiple storage compartments 910 can be arranged inside the cylinder 930 Evenly distributed, when switching the position of a certain storage partition, the rotation angle of the rotating storage box 900 can be pre-calculated according to the current position of the storage partition, and then the rotating storage box 900 can be controlled according to the calculated rotation angle, so that The rotation process is controllable.

In some optional embodiments, the rotating storage box 900 further includes a central rotating shaft 940 and a plurality of partition boards.

The central rotating shaft 940 extends upward from the center of the chassis. The plate surface of each partition board extends in the vertical direction, and extends radially outward from the outer surface of the central rotating shaft 940 to the inner surface of the barrel 930, so as to space out a plurality of top openings inside the barrel 930. Storage compartment 910. A boundary is defined between every two adjacent partition boards A storage partition.

With the above structure, each storage partition can switch positions accordingly as the rotating storage box 900 rotates, and the rotation pace of each storage partition remains consistent.

In some optional embodiments, the first storage area 650 has a vent 610 for introducing external air to adjust the internal atmosphere using external air. For example, the vent 610 of the first storage area 650 can be connected to its external environment through a pipeline and receive gas from its external environment, such as oxygen-rich gas, oxygen-poor gas, or other gases, so that the first storage area 650 Create a high-oxygen fresh-keeping atmosphere, a low-oxygen fresh-keeping atmosphere or other controlled atmosphere atmosphere inside.

Each storage compartment 910 is provided with a ventilation opening to allow external air to enter the storage area through the ventilation opening when switching to the first storage area 650 . In one example, the top opening of each storage compartment 910 serves as a ventilation opening of the storage compartment 910 . In another example, the barrel 930 may be provided with openings or air holes as ventilation ports.

With the above structure, since the first storage area 650 can use external air to adjust the internal atmosphere, and the storage compartment 910 is provided with a ventilation port that allows external air to enter the storage partition, therefore, when a certain storage partition is switched to the third storage area, When a storage area 650 is provided, the storage atmosphere of the storage area and the first storage area 650 can be kept consistent.

In an optional embodiment, the first storage area 650 is provided on the rear side of the second storage area 680 . The storage container 600 is pullably disposed in the box 100 . FIG. 4 is another schematic exploded view of the internal structure of the refrigeration and freezing device 10 shown in FIG. 2 . The back wall of the storage container 600 is provided with a vent 610 connected to the first storage area 650 . For example, the storage container 600 may be pullably disposed on the base. The base is pullably installed in the storage room.

In one example, the storage container 600 is further provided with a first sealing cover 660 and a second sealing cover 690 . The first sealing cover 660 is used to seal the first storage area 650, and the second sealing cover 690 is used to seal the second storage area 680. Each sealing cover is respectively provided with a grab handle for the user to grab, thereby opening the first storage area 650 or the second storage area 680 .

The number of storage containers 600 may be at least one, and the number thereof may be set according to actual needs. When there are multiple storage containers 600, different types of food can be stored separately to avoid odor mixing or mutual contamination.

In a further embodiment, the refrigeration and freezing device 10 may further include a driving mechanism including a motor. The output shaft of the motor is drivingly connected to the central rotating shaft of the rotating storage box 900, and is used to drive the central rotating shaft of the rotating storage box 900 to rotate, thereby driving the entire rotating storage box 900 to rotate.

In another example, the output shaft of the motor may be transmission-connected to the chassis of the rotating storage box 900 for driving the chassis of the rotating storage box 900 to rotate, thereby driving the entire rotating storage box 900 to rotate.

In another example, the refrigeration and freezing device 10 may not be provided with a driving mechanism. In this case, the user can manually drive the rotating storage box 900 to rotate.

The refrigeration and freezing device 10 further includes a gas circuit assembly, which has a ventilation pipe 820 that communicates with the ventilation port 610 and is used to transport gas to the first storage area 650 . The ventilation pipe 820 is fixed on the rear side of the storage container 600 . And the ventilation pipe 820 and the ventilation port 610 are nested with each other and can be detachably arranged during the pulling process of the storage container 600 .

By arranging the air circuit assembly in the storage room, and allowing the ventilation pipe 820 and the ventilation port 610 of the air circuit assembly to be nested in and detachable from each other during the pulling process of the storage container 600, in the storage room, Object container 600 is extracted At this time, since the vent 610 moves synchronously with the storage container 600, the vent pipe 820 and the vent 610 are disengaged and separated from each other. When the storage container 600 is reset, the vent pipe 820 and the vent 610 are Can be restored to a nested state and thus connected to each other. Using the above solution of this embodiment, the storage container 600 can receive external air while being pullable to adjust the internal atmosphere.

In some optional embodiments, the vent 610 is hollow cylindrical and protrudes outward from the back wall of the storage container 600 . One end of the ventilation pipeline 820 has a hollow cylindrical interface in which the ventilation port 610 is nested.

When the vent 610 is hollow cylindrical and bulges outward from the back wall of the storage container 600, one end of the vent pipe 820 is set as a hollow cylindrical interface for the vent 610 to be nested therein. When the storage container 600 is When withdrawing, since the vent 610 moves synchronously with the storage container 600, the vent 610 comes out of the hollow cylindrical interface to achieve disengagement. When the storage container 600 is reset, the vent 610 can be inserted into the hollow cylindrical interface again. within to achieve nesting. Using the above solution of this embodiment, it is possible to ensure airtight connection between the storage container 600 and the ventilation pipe 820, thereby improving the air conditioning efficiency.

In some optional embodiments, the air circuit assembly also has a mounting bracket 850, which is fixed in the storage compartment. For example, the mounting bracket 850 may be fixedly connected to the inner wall of the storage compartment. Methods of fixed connection include but are not limited to screwing, clamping, welding, and riveting.

The mounting bracket 850 has a hollow cylindrical channel into which the vent pipe 820 is inserted to achieve fixed assembly. That is to say, the ventilation pipeline 820 is fixedly connected to the mounting bracket 850 to achieve fixation.

By using the mounting bracket 850 to fix the ventilation pipe 820, the ventilation pipe 820 can be fixed at any position away from the inner wall of the storage room, which improves the position flexibility of the ventilation pipe 820.

In some optional embodiments, the mounting bracket 850 includes a body portion 851 and a cover portion 852 . Among them, the main body part 851 is fixed in the storage compartment, and defines a concave arc-shaped plate that is concave downward and arc-shaped; the concave arc-shaped plate serves as the lower channel wall of the hollow cylindrical channel.

The cover body portion 852 defines an upwardly concave arc-shaped plate that is concave and arc-shaped as the upper channel wall of the hollow cylindrical channel. The upper channel wall and the lower channel wall together form a fixing part.

The main body part 851 and the cover body part 852 can be separately provided and are not integrally formed. The body part 851 and the cover part 852 jointly define a hollow cylindrical channel for arranging the ventilation pipe 820. Since the body part 851 and the cover part 852 can be separated and independently arranged, when assembling the ventilation pipe 820, it is possible to First place the ventilation pipe 820 on the concave arc plate of the body part 851, and then fix the cover part 852 on the body part 851. In this way, the ventilation pipe 820 can be stably assembled in the hollow cylindrical shape. inside the channel. And when it is necessary to disassemble the ventilation pipe 820, just separate the body part 851 and the cover part 852, and the disassembly process is simple.

The cover portion 852 is detachably assembled above the main body portion 851 . The cover portion 852 also defines first threaded holes on both sides of the upper channel wall. The body part 851 is correspondingly formed with second threaded holes located on both sides of the lower channel wall and opposite to the first threaded holes, so as to achieve detachable assembly through screwing.

In one example, the vent 610 is located on the back wall of the storage container 600 . For example, the body portion 851 can be disposed in close contact with the back wall of the storage container 600 .

The mounting bracket 850 also includes a bending portion 854, which is formed by bending forward or backward from the end of the body portion 851, and is disposed in close contact with the side wall of the storage compartment. The bent portion 854 is provided with a third threaded hole for passing the screw Then the bent portion 854 is fixedly assembled to the side wall of the storage compartment.

When the vent 610 is opened on the back wall of the storage container 600, the body part 851 is fixed to the rear side of the storage container 600, and the bending part 854 bent forward is connected to the end of the body part 851, Since the bending portion 851 can be fixedly connected to the side wall of the storage compartment through screwing, based on the above structure, on the one hand, the mounting bracket 850 of the air path assembly can be stably assembled in the storage compartment to fix it. The joint between the air conditioning pipeline 440 and the vent 610 can, on the other hand, fix the body part 851 at any position away from the back wall of the storage compartment, so that there is a gap between the body part 851 and the back wall of the storage compartment. Leave enough space for piping.

The vent 610 is in the shape of a hollow column, and it bulges outward from the back wall of the storage container 600 and at least partially extends into the hollow cylindrical channel. The first end 821 of the vent line 820 defines a hollow cylindrical interface into which the vent 610 is nested.

When the vent 610 is hollow cylindrical and bulges outward from the back wall of the storage container 600, the first end of the vent pipe 820 is set as a hollow cylindrical interface for the vent 610 to be nested in the storage container. When 600 is withdrawn, since the vent 610 moves synchronously with the storage container 600, the vent 610 comes out of the hollow cylindrical interface to achieve disengagement. When the storage container 600 is reset, the vent 610 can be inserted into the hollow cylinder again. within the interface to achieve nesting. Using the above solution of this embodiment, it is possible to ensure airtight connection between the storage container 600 and the ventilation pipe 820, thereby improving the air conditioning efficiency.

In some optional embodiments, the second end of the vent line 820 has another hollow cylindrical interface. And the refrigeration and freezing device 10 also includes a transfer pipeline 810 that communicates with the second end of the ventilation pipeline 820 and is used to transport gas.

FIG. 5 is a schematic structural diagram of the transfer pipeline 810 of the refrigeration and freezing device 10 shown in FIG. 4 . FIG. 6 is a schematic perspective view of the transfer pipeline 810 of the refrigeration and freezing device 10 shown in FIG. 4 . The interior of the transfer pipe 810 defines an air flow channel 813 that is inclined relative to the horizontal plane. Storage spaces are generally cooler. Since the transfer pipeline 810 is directly connected to the ventilation port 610 of the storage container 600 via the ventilation pipeline 820 and is close to the storage space, when the temperature of the storage space is low, the temperature of the transfer pipeline 810 is also low. Correspondingly lower.

By arranging the air flow channel 813 of the transfer pipe 810 to be inclined relative to the horizontal plane, the angle between the air flow channel 813 and the horizontal plane can form an acute or right angle. When the gas flowing through the transfer pipe 810 contains moisture and the temperature of the storage space is When the temperature is low, the moisture carried by the gas is not easily retained inside the air flow channel 813, which is helpful to reduce or avoid the air flow channel 813 being blocked due to frost and dew, so as to achieve sustainable gas exchange between the storage space and its external environment. This enables the storage space to maintain a low-temperature preservation atmosphere for a long time.

The transfer pipeline 810 has a first interface 811 connected to the air conditioning pipeline 440 and a second interface 812 connected to the ventilation pipeline 820, and the above-mentioned air flow channel 813 is connected between the second interface 812 and the first interface 811, so that the air conditioning The pipeline 440 is connected to the vent 610 .

The first interface 811 and the second interface 812 are respectively hollow cylindrical interfaces formed by bulging outward from the outer surface of the transfer pipe 810 . The first interface 811 and the second end of the air conditioning pipeline 440 are nested with each other and are detachably provided. The second interface 812 and another hollow cylindrical interface are nested in each other and are detachably arranged.

The interiors of the first interface 811 and the second interface 812 respectively define hollow passages that communicate with the airflow passage 813 and are inclined relative to the horizontal plane. That is, the hollow channel of the first interface 811 and the hollow channel of the second interface 812 are also respectively arranged at an angle.

With the above structure, since the hollow channel of each interface is connected to the air flow channel 813, this is equivalent to extending the path of the inclined section of the transfer pipeline 810, which can further reduce the risk of air blockage in the transfer pipeline 810, making Maintain a smooth connection between the air conditioning pipeline 440 and the vent 610 .

In some optional embodiments, the airflow channel 813 of the transfer pipeline 810 includes a first channel section 813a and a second channel section 813b. Among them, the first channel section 813a is connected to the hollow channel inside the first interface 811. The second channel section 813b is connected to the first channel section 813a and to the hollow channel inside the second interface 812 .

The degree of inclination of the second channel section 813b is set to be different from the degree of inclination of the first channel section 813a. In other words, the angle between the second channel section 813b and the horizontal plane is different from the angle between the first channel section 813a and the horizontal plane, which will cause the liquid carried by the gas to flow through the first channel section 813a and the second channel section 813a. The flow rates of the two channel sections 813b are different.

By arranging two channel sections with different inclinations in the transfer pipeline 810, on the one hand, the connection method between each channel section and the corresponding interface can be simplified, and on the other hand, since the gas flows through the first channel section 813a The flow rate is different from that in the second channel section 813b. Therefore, the above solution of this embodiment can further reduce the risk of airway blockage in the airflow channel 813.

In some optional embodiments, the angle between the first channel section 813a and the horizontal plane is greater than the angle between the second channel section 813b and the horizontal plane.

Using the above solution, when the air conditioning pipeline 440 delivers gas to the storage space, even the liquid carried by the gas may condense in the first channel section 813a and the second channel section 813b, because the liquid carried by the gas It will first condense in the first channel section 813a, and the flow rate of the liquid droplets is relatively large. When these liquid beads enter the second channel section 813b, they will wash the surface of the second channel section 813b, enveloping the second channel section 813b. The condensed liquid beads continue to flow forward at a high speed, thereby effectively reducing the risk of air blockage in the transfer pipeline 810 .

In some optional embodiments, the first interface 811 is formed in the upper section of the transfer pipeline 810 , and the hollow channel inside the first interface 811 is inclined upward in a direction away from the outer surface of the transfer pipeline 810 . The central axis of the first channel section 813a is coaxial with the central axis of the hollow channel inside the first interface 811. That is to say, the inclination degree of the hollow channel inside the first interface 811 is the same as the inclination degree of the first channel section 813a.

The second interface 812 is formed in a side section of the transfer pipe 810 and is located below the second interface 812 . The hollow channel inside the second interface 812 is inclined downward in a direction away from the outer surface of the transfer pipe 810 . The central axis of the second channel section 813b is coaxial with the central axis of the hollow channel inside the second interface 812. That is, the inclination degree of the hollow channel inside the second interface 812 is the same as the inclination degree of the second channel section 813b.

Based on the above structure, the air conditioning pipeline 440 can be connected to the upper part of the transfer pipeline 810 , and the ventilation pipeline 820 can be connected to the side of the transfer pipeline 810 .

In one example, the port of the air conditioning pipeline 440 can be nested in the hollow channel of the first interface 811 , and the ventilation pipeline 820 can be nested in the hollow channel of the second interface 812 .

In one example, vent line 820 is made of elastic material. Since the ventilation pipe 820 made of elastic material can closely fit the interface nested therein, using the ventilation pipe 820 to connect the second interface 812 and the ventilation port 610 can make the second interface 812 and the ventilation port 610 are airtightly joined.

In some optional embodiments, the refrigeration and freezing device 10 further includes an oxygen treatment device 300 and an air conditioning pipeline 440 . Among them, the oxygen treatment device 300 has a housing 320 and an electrode pair. The interior of the housing 320 defines an electrochemical reaction chamber containing electrolyte. The electrode pair is arranged in the electrochemical reaction chamber and is used to transfer external oxygen to the electrolyte through an electrochemical reaction. Electrochemical reaction chamber. The housing 320 is provided with an exhaust hole 323 connected to the electrochemical reaction chamber for exhausting oxygen from the electrochemical reaction chamber.

The first end of the air conditioning pipeline 440 is used to communicate with the ventilation pipeline 820, and the second end of the air conditioning pipeline 440 is used to communicate with the exhaust hole 323 to transport oxygen in the electrochemical reaction chamber to the first storage area. 650, thereby creating a high-oxygen fresh-keeping atmosphere in the first storage area 650. For example, the first end of the air conditioning pipeline 440 can be directly connected to the switching pipeline 810 , and the second end can be directly connected to the exhaust hole 323 .

Using the above structure, the multiple storage compartments 910 of the rotating storage box 900 can be switched back and forth between the high-oxygen fresh-keeping area and the non-high-oxygen fresh-keeping area. When the air conditioning pipeline 440 is used to transport oxygen from the electrochemical reaction chamber to the first storage area 650, the first storage area 650 can create a high-oxygen preservation environment. When the storage area 650 is switched to the second storage area 680, the storage compartment can be switched from the high oxygen preservation area to the non-high oxygen preservation area. When a certain storage compartment 910 is switched from the second storage area 680 to the first storage area, When the storage area is 650, the storage compartment 910 can be switched from a non-high oxygen preservation area to a high oxygen preservation area. Therefore, using the above solution of this embodiment, different storage partitions of the refrigeration and freezing device 10 can be divided into a high oxygen preservation area and a non-high oxygen preservation area. Switch back and forth between oxygen preservation zones.

Under the action of the air circuit assembly, air flow communication can be achieved between the air conditioning pipeline 440 and the ventilation port 610 through the transfer pipeline 810 and the ventilation pipeline 820 . The transfer pipe 810 and the vent pipe 820 are used to cleverly connect the air conditioning pipe 440 and the vent 610. There is no need to directly seal the connection between the port of the air conditioning pipe 440 and the vent 610, which is conducive to simplifying refrigeration and freezing. The communication method between the vent 610 of the device 10 and the air conditioning pipeline 440.

Figure 7 is a schematic structural diagram of the oxygen treatment device 300 of the refrigeration and freezing device 10 according to an embodiment of the present invention. FIG. 8 is a schematic exploded view of the oxygen treatment device 300 of the refrigeration and freezing device 10 shown in FIG. 7 .

The electrode pair may include a cathode plate 330 and an anode plate 340. The electrochemical reaction chamber is a place where the cathode plate 330 and the anode plate 340 perform electrochemical reactions. It can contain an alkaline electrolyte, such as 1 mol/L NaOH, and its concentration can be adjusted according to actual needs.

Housing 320 has lateral openings 321 . For example, the housing 320 may be in the shape of a flat rectangular parallelepiped. The lateral opening 321 can be provided on any surface of the housing 320, such as the top surface, bottom surface or side surface. In one example, the lateral opening 321 may be provided on the surface of the housing 320 with the largest area.

The cathode plate 330 is disposed at the lateral opening 321 to jointly define an electrochemical reaction chamber for containing electrolyte and consuming oxygen through an electrochemical reaction together with the housing 320 . Oxygen in the air can undergo a reduction reaction at the cathode plate 330, namely: O ₂ +2H ₂ O+4e ^- → 4OH ^- .

The anode plate 340 and the cathode plate 330 are spaced apart from each other and are arranged in the electrochemical reaction chamber, and are used to provide reactants to the cathode plate 330 and generate oxygen through electrochemical reactions. The OH ^- generated by the cathode plate 330 can undergo an oxidation reaction at the anode plate 340 and generate oxygen, that is: 4OH ^- →O ₂ +2H ₂ O+4e ^- .

The above examples of the electrochemical reaction of the cathode plate 330 and the anode plate 340 are only illustrative. Based on understanding the above embodiments, those skilled in the art should easily change the type of electrochemical reaction, or adapt it to other electrochemical reactions. The structure of the reaction type oxygen treatment device 300 is expanded, and these transformations and extensions All developments shall fall within the protection scope of the present invention.

In one example, the first end of the air conditioning pipeline 440 may be directly connected to the transfer pipeline 810 . The second end of the air conditioning pipeline 440 may be directly or indirectly connected to the exhaust hole 323 .

In some optional embodiments, the housing 320 is provided with a fluid replenishing port 322 connected to the electrochemical reaction chamber. The refrigeration and freezing device 10 also includes a liquid storage module 500, which is disposed in the box 100 and has a box body 510. The interior of the box body 510 defines a liquid storage space for storing liquid, and the liquid storage space is connected to the liquid replenishment port 322. To replenish electrolyte to the electrochemical reaction chamber. The liquid contained in the liquid storage space may be water or electrolyte, and its concentration may be lower than the electrolyte contained in the electrochemical reaction chamber.

An air inlet 512 and an air outlet 513 are provided on the top wall of the box 510 . The air inlet 512 is connected to the exhaust hole 323 to allow the oxygen discharged from the exhaust hole 323 to pass into the liquid storage space to filter soluble impurities, such as the electrolyte carried by the oxygen. The air outlet 513 is used to allow filtered oxygen to be discharged outward, and is directly connected to the second end of the air conditioning pipeline 440 .

Using the above structure, the air conditioning pipeline 440 can deliver clean oxygen to the storage space.

In one example, the refrigeration and freezing device 10 may include an inner bladder 120 and an inner bladder 150 . In the above embodiments, the storage container 600 may be disposed inside the inner bladder 150 . The inner bladder 150 may define a temperature-changing compartment 152 or a freezing compartment 152 . The inner bladder 120 defines another storage compartment, such as a refrigeration compartment, and the storage compartment may define another storage space 122. For convenience of distinction, this storage space may be named a second storage space. The cathode plate of the oxygen treatment device 300 is in gas flow communication with the storage space 122, thereby reducing the oxygen content in the storage space through an electrochemical reaction.

In one example, the oxygen treatment device 300 may be disposed within the foam layer. Figure 9 is a schematic structural diagram of a refrigeration and freezing device according to an embodiment of the present invention. Figure 10 is a schematic internal structural diagram of the refrigeration and freezing device shown in Figure 9. In order to facilitate illustrating the structure and connection relationship of each component, in the figure The foaming layer is hidden. At this time, the refrigeration and freezing device 10 may further include a ventilation pipeline 200 embedded in the foam layer. The ventilation pipeline 200 may include an air intake pipeline 210 and a return air pipeline 220 .

The air inlet pipe 210 is used to guide the gas in the storage space 122 to the cathode plate 330 , and the return pipe 220 is used to guide the gas flowing through the cathode plate 330 back to the storage space 122 to reduce the oxygen in the storage space 122 . content. For example, a first ventilation port connected to the first end of the air inlet pipeline 210 and a second ventilation port connected to the first end of the return air pipeline 220 are formed on the wall of the inner tank 120 . Each ventilation port is an opening formed on the wall of the inner bladder 120 . The second end of the air inlet pipe 210 and the second end of the return air pipe 220 can be connected to the two ends of the cathode plate 330 respectively. Specifically, the second end of the air inlet pipe 210 can be connected to the upwind side of the cathode plate 330 and the return air pipe. The second end of 220 can be connected to the leeward side of the cathode plate 330, so that the gas flowing out of the air inlet pipe 210 can flow into the return air pipe 220 after flowing through the cathode plate 330.

Using the above structure, the air inlet pipe 210 and the air return pipe 220 are used to connect the storage space 122 and the oxygen treatment device 300. The gas with a high oxygen content in the storage space 122 can flow to the cathode plate 330 through the air inlet pipe 210. The cathode plate 330 uses the oxygen in it as a reactant to perform an electrochemical reaction to form hypoxic gas with lower oxygen content. These hypoxic gases can be returned to the storage space 122 through the return pipeline 220, thereby reducing the storage space. 122The role of oxygen content.

The oxygen treatment device 300 can be disposed at any part of the foam layer, for example, it can be disposed on the back of the liner 120 , or can be disposed on the top, bottom, and side of the liner 120 . For a French-style refrigerator or a T-type refrigerator, in one example, the oxygen treatment device 300 may be disposed in the gap between the upper inner pot 120 and the lower inner pot 120 .

In some optional embodiments, the side of the foam layer facing away from the inner bladder 120 is provided with an assembly groove that communicates with the external environment of the foam layer for assembling the oxygen treatment device 300 .

After the foam layer is formed, the oxygen treatment device 300 can be assembled into the assembly groove to be disposed in the foam layer. Assembly grooves can be reserved during the foam layer forming process. The assembly groove is recessed along the thickness direction of the foam layer toward the inner bladder 120 and forms a gap with the inner bladder 120 . In other words, the assembly groove does not penetrate the foam layer, so that the oxygen treatment device 300 assembled to the assembly groove will not be close to the inner bladder 120 . That is, a certain thickness of heat insulation material is formed between the inner tank 120 and the oxygen treatment device 300 .

Using the above structure, by opening an assembly groove on the side of the foam layer facing away from the liner 120 that communicates with the external environment of the foam layer, and forming a gap between the assembly groove and the liner 120, the oxygen treatment device 300 can be The foam layer is formed and then installed into the assembly groove, which helps to simplify the difficulty of disassembly and assembly of the oxygen treatment device 300 . Moreover, since the oxygen treatment device 300 is not close to the inner tank 120, the solution of this embodiment can reduce or prevent the low-temperature environment of the refrigeration and freezing device 10 from affecting the normal progress of the electrochemical reaction.

The oxygen treatment device 300 can be fixed in the assembly groove, and the fixing method includes but is not limited to screwing, snapping, riveting, welding, and bonding.

In some optional embodiments, the box body 100 further includes a box shell 170 , which is covered on the outside of the foam layer to sandwich the foam layer with the inner bladder 120 . The box shell 170 has a back plate, and an assembly groove is formed between the back wall of the inner bladder 120 and the back plate of the box shell 170 . That is to say, the oxygen treatment device 300 of this embodiment is disposed in the foam layer on the back of the inner bladder 120 . The back plate of the box shell 170 can close the opening of the assembly groove to improve the appearance.

In one example, the back plate of the box shell 170 can be provided with an installation opening facing the assembly groove. During the assembly process, there is no need to disassemble the back plate of the box shell 170 , and the oxygen treatment device 300 can be directly fixed to the assembly through the installation opening. inside the groove. In a further example, a cover plate may be provided at the installation opening to cover the installation opening to improve the appearance. In another example, the oxygen treatment device 300 can be fixed into the assembly groove first, and then the back plate of the box shell 170 is covered on the back of the foam layer.

With the above structure, the oxygen treatment device 300 does not need to be pre-installed in the foaming layer to prevent the foaming process from adversely affecting the structure and performance of the oxygen treatment device 300 , and the assembly process of the oxygen treatment device 300 can be done on the back of the refrigeration and freezing device 10 Execution, with the advantages of simple assembly process.

In yet another example, a compressor chamber for installing a compressor is also defined within the box 100 . The oxygen treatment device 300 may be installed in the compressor chamber. For example, a support plate for fixing the compressor is provided at the bottom of the compressor chamber, and the oxygen treatment device 300 can be directly or indirectly disposed on the support plate.

In one example, the box body 510 is disposed within the foam layer. By arranging the box body 510 of the liquid storage module 500 in the foam layer, and making the liquid storage space of the box body 510 communicate with the oxygen treatment device 300, the liquid stored in the box body 510 can be used to replenish the oxygen treatment device 300. Electrolyte, since the box 510 does not occupy the storage space 122, the refrigeration and freezing device 10 can use the liquid storage module 500 without affecting the volume ratio. The electrolyte is replenished to the oxygen treatment device 300 so that the oxygen treatment device 300 can continuously adjust the oxygen content of the storage space 122 .

The box body 510 of the liquid storage module 500 can be disposed at any part of the foam layer, for example, it can be disposed on the side of the inner bladder 120 , or can be disposed on the top, bottom and back of the inner bladder 120 . For a French-style refrigerator or a T-shaped refrigerator, in one example, the box body 510 of the liquid storage module 500 may be disposed in the gap between the upper inner pot 120 and the lower inner pot 150 .

In some optional embodiments, the box body 100 also has a box shell 170, and a foam layer is formed between the box shell 170 and the inner bladder. The box shell 170 is covered on the outside of the foam layer to sandwich the foam layer with the inner container. In one example, the refrigeration and freezing device may include a refrigeration inner pot, a variable temperature inner pot, and a freezing inner pot. In a further example, the box body can be disposed in the foam layer outside the refrigerated inner bag.

Figure 11 is a schematic structural diagram of the inner bladder 120 of the refrigeration and freezing device 10 according to an embodiment of the present invention. The liner 120 is provided with an opening-shaped interactive window 124, and the foam layer has an installation groove communicating with the interactive window 124 for assembling the liquid storage module 500. After the foam layer is formed, the liquid storage module 500 can be assembled into the installation groove, thereby being disposed in the foam layer. The installation groove can be reserved during the foam layer forming process. The installation groove is recessed in a direction away from the interaction window 124 along the thickness direction of the foam layer, and forms a gap with the box shell 170 . In other words, the mounting groove does not penetrate the foam layer, so that the liquid storage module 500 assembled into the mounting groove will not be tightly attached to the tank shell 170 . That is, a certain thickness of heat insulation material is formed between the box shell 170 and the oxygen treatment device 300 .

With the above structure, the liquid storage module 500 does not need to be pre-installed in the foaming layer to prevent the foaming process from adversely affecting the structure and performance of the liquid storage module 500 , and the assembly process of the liquid storage module 500 can be performed in the storage space 122 , with the advantages of simple assembly process.

By opening the interactive window 124 on the inner liner 120, and providing a mounting groove communicating with the interactive window 124 in the foam layer, and forming a gap between the mounting groove and the case shell 170, the liquid storage module 500 can be foamed. The layer is formed and then installed into the installation groove, which helps to simplify the difficulty of disassembly and assembly of the liquid storage module 500 . Moreover, since the installation groove does not penetrate the foam layer, the solution of this embodiment can reduce or avoid the obvious reduction in the thermal insulation performance of the refrigeration and freezing device 10 caused by installing the liquid storage module 500 in the foam layer.

The liquid storage module 500 can be fixed in the installation groove, and the fixing method includes but is not limited to screwing, snapping, riveting, welding, and bonding.

In some optional embodiments, the box body 510 is provided with a liquid injection port 514 connected to the liquid storage space, and the liquid injection port 514 is exposed through the interactive window 124, thereby allowing external liquid to be injected into the liquid storage space. FIG. 12 is a schematic structural diagram of the liquid storage module of the refrigeration and freezing device shown in FIG. 10 . FIG. 13 is a schematic perspective view of the liquid storage module of the refrigeration and freezing device shown in FIG. 12 . For example, the liquid filling port 514 is disposed on the side wall of the box body 510 facing the storage space 122 so as to be exposed through the interactive window 124 .

By opening an interactive window 124 on the inner tank 150 and connecting the liquid filling port 514 of the box 510 to the storage space 122 through the interactive window 124, the interactive window 124 can be used as an operation window for the user to add liquid to the liquid storage space. Since the interactive window 124 can expose the liquid injection port 514, when the liquid storage volume of the liquid storage space is insufficient, external liquid can be injected into the liquid storage space through the liquid injection port 514. Therefore, the above solution of this embodiment can simplify the liquid storage module. 500 The liquid replenishment method enables the liquid storage module 500 to replenish the electrolyte to the oxygen treatment device 300 continuously.

The box body 510 is provided with a cover 550, and the cover 550 is reciprocally disposed at the liquid filling port 514 to open or close the liquid filling port 514. When the cover 550 opens the liquid filling port 514, the liquid filling port 514 is allowed to be exposed. By providing the cover 550 on the box body 510 and using the cover 550 to open or close the liquid filling port 514, the liquid filling port 514 can be opened only when receiving external liquid, thereby reducing or preventing foreign matter from entering the liquid storage space. , to keep the liquid stored in the liquid storage space clean.

The cover 550 may be a push-type pop-up cover that can rotate and pop up under pressure to at least partially extend into the storage space 122 through the interaction window 124 to open the liquid filling port 514 .

In one example, the bottom of the cover 550 may be connected to the box body 510 through a rotating shaft and be pivotably connected to the box body 510 . When the lid body 550 closes the liquid filling port 514, its outer surface is coplanar with the outer surface of the box body 510. At this time, the top of the lid body 550 can be connected to the box body 510 through the snap-in structure; when it is necessary to open the liquid filling port 514 , the top of the cover 550 can be pressed to separate the top of the cover 550 from the box 510. At this time, the cover 550 can rotate around the rotating axis and at least partially extend into the storage space 122, thereby opening the liquid filling port 514.

After understanding the embodiments of the present disclosure, those skilled in the art should easily understand the assembly structure between the push-type spring cover and the box body 510 , which will not be described in detail in this disclosure.

In some optional embodiments, at least a portion of the box body 510 is made of a transparent material to form a visible area 516 for revealing the liquid storage volume of the box body 510 . The transparent material may be polymethyl methacrylate, polycarbonate, polyethylene terephthalate, or polypropylene.

The visible area 516 of this embodiment is exposed through the interactive window 124 . The visible area 516 extends longitudinally and is located below the liquid filling port 514 . For example, the visible area 516 is also provided on the side wall of the box 510 facing the storage space 122 so as to be exposed through the interactive window 124 .

By arranging the visible area 516 on the box body 510 and making the visible area 516 opposite to the interactive window 124, the interactive window 124 can be used as an observation window for the user to observe the liquid level in the liquid storage space. Since the interactive window 124 can reveal the visible area 516, the user can easily observe the liquid storage volume in the liquid storage space. Therefore, the above solution of this embodiment can enable the user to obtain an intuitive interactive experience. When the liquid storage volume in the liquid storage space is insufficient, the user can take rehydration measures in a timely manner.

In one example, the interactive window 124 may be located on the side wall of the inner bladder 150 , and the mounting groove is correspondingly disposed between the side wall of the inner bladder 150 and the side wall of the box shell 170 .

Since the side wall of the inner tank 150 is not easily blocked by the items stored in the storage space 122 and is close to the user's movable area, an interactive window 124 is provided on the side wall of the inner tank 150 to allow the liquid to be stored. The module 500 is embedded in the foam layer on the side of the box 100, which can reduce the difficulty of interaction between the user and the liquid storage module 500 to a certain extent. The user can quickly obtain the stored liquid without moving the items stored in the storage space 122. The liquid storage capacity information of the module 500 is stored, and the liquid replenishment operation can be performed in time when the liquid storage capacity of the liquid storage module 500 is insufficient.

In some optional embodiments, the liquid storage module 500 may further include a liquid level sensor, which is disposed in the liquid storage space and used to detect the liquid level in the liquid storage space. When the liquid level sensor detects that the liquid level in the liquid storage space is lower than the set value, the refrigeration and freezing device 10 can send out an alarm signal. For example, the alarm signal can be transmitted to the user through wireless transmission technology to remind the user to replenish liquid in time.

In some further examples, the box body 510 has a first side wall flush with the side wall of the inner bladder 150 and closing the interaction window 124 and a second side wall opposite the first side wall and hidden inside the mounting groove. . The liquid filling port 514 is located on the first side wall. The opening area of the interactive window 124 and the surface area of the first side wall of the box body 510 can be approximately the same, so that the first side wall of the box body 510 just closes the interactive window 124 and the outer surface of the first side wall is in contact with the side wall of the inner bladder 150 The inner surfaces are connected into a complete plane to make the appearance beautiful.

The liquid filling port 514 may be provided in the upper section of the first side wall. The visible area 516 can also be provided on the first side wall, for example, it can be provided on the middle section or the lower section of the first side wall.

The box body 510 may be generally in the shape of a flat rectangular parallelepiped. The box body 510 is provided with a liquid outlet 511 communicating with the liquid storage space. The box body 510 also has a top wall and a bottom wall connected between the first side wall and the second side wall and arranged oppositely in the vertical direction. A liquid outlet 511 is provided on the bottom wall, and the liquid outlet 511 is connected to the liquid replenishing port 322 to replenish electrolyte to the electrochemical reaction chamber.

In some optional embodiments, the box body 510 further has third side walls and fourth side walls connected between the first side wall and the second side wall and arranged oppositely in the horizontal direction. A fixing piece 517 is connected to the outer surface of the third side wall and/or the fourth side wall, and the fixing piece 517 has a screw hole for cooperating with a screw to fix the box body 510 to the mounting groove.

The refrigeration and freezing device 10 also includes a fluid replenishment pipeline 420 embedded in the foam layer. The first end of the fluid replenishment pipeline 420 is connected to the fluid replenishment port 322 of the oxygen treatment device 300 , and the second end of the fluid replenishment pipeline 420 is connected to the liquid storage module 500 The liquid outlet 511 is provided to guide the liquid flowing out of the liquid storage space from the liquid outlet 511 to the liquid replenishment port 322, thereby replenishing liquid to the electrochemical reaction chamber. The liquid outlet 511 is higher than the liquid replenishing port 322. In this way, the liquid in the liquid storage space can automatically flow into the electrochemical reaction chamber under the action of gravity without the need for a power device.

Of course, in other examples, the liquid outlet 511 can also be transformed to be lower than the liquid replenishment port 322 or be level with the liquid replenishment port 322 . At this time, a pump can be installed on the liquid replenishing pipeline 420 to drive the liquid in the liquid storage space to flow into the electrochemical reaction chamber under the action of the pump; or the siphon principle can be used to cause the liquid in the liquid storage space to flow into the electrochemical reaction chamber. .

In some further examples, a one-way valve may be provided on the fluid replacement pipeline 420 to allow one-way passage of liquid from the liquid outlet 511 to ensure one-way flow of liquid flowing through the fluid replacement pipeline 420 .

The refrigeration and freezing device 10 also includes a filter pipeline 430 embedded in the foam layer. The first end of the filter pipeline 430 is connected to the exhaust hole 323 of the oxygen treatment device 300 , and the second end of the filter pipeline 430 is connected to the box 510 The air inlet 512 is used to guide the oxygen flowing out from the exhaust hole 323 to the air outlet 513, so as to enter the liquid storage space for filtration.

The liquid storage module 500 may further include an air filter pipe 540 and an air outlet pipe. Among them, the air filter pipe 540 is inserted into the liquid storage space from the air inlet 512 and extends to the bottom section of the liquid storage space to guide the oxygen to be filtered to the liquid storage space so that the soluble impurities in the oxygen are dissolved in the liquid storage space. . The air outlet pipe is inserted into the box body 510 from the air outlet 513, and extends to the upper section of the liquid storage space, and is located above the liquid stored in the liquid storage space, so as to guide the filtered oxygen out through it.

Using the above solution, the oxygen to be filtered can reach the liquid storage space under the guidance of the air filter pipe 540, and flow through the liquid stored in the liquid storage space, so that the soluble impurities in the oxygen are dissolved in the liquid storage space, completing the purification of the gas. The purified gas can flow into the designated space under the guidance of the air outlet pipe, thereby regulating the oxygen in the space. The role of content.

In an optional embodiment, the liquid storage module 500 further includes an air blocking mechanism 530, which is disposed in the liquid storage space and separates the liquid storage space into a gas filter area and a non-gas filter area where the air path is blocked. The gas filter area is used to allow the gas flowing into the air inlet 512 to flow therethrough to achieve filtration. The non-filtered area is used to receive liquid from the outside.

The air filter area and the non-air filter area can be arranged side by side in the transverse direction. The air blocking mechanism 530 blocks a part of the liquid path between the air filter area and the non-air filter area, so that the air filter area and the non-air filter area can be blocked when the air path is blocked. Keep the fluid path connected. For example, the air blocking mechanism 530 is a partition-like structure located between the air filter area and the non-air filter area and extends downward from the lower surface of the top wall of the box body 510 and forms a gap with the upper surface of the bottom wall of the box body 510 . The air filtering area is located on one lateral side of the air blocking mechanism 530 , and the non-air filtering area is located on the other lateral side of the air blocking mechanism 530 . The air inlet 512 and the air outlet 513 can be respectively provided on the top wall of the area where the air filter area is located. The liquid injection port 514 can be provided on the top wall of the area where the non-air filter area is located.

Using the above structure, by arranging the air blocking mechanism 530 in the liquid storage space, and using the air blocking mechanism 530 to separate the liquid storage space into a filtered air area and a non-air filtered area where the air path is blocked, it is possible to execute the operation only in the air filtered area. Gas purification function. Since the air filter area is only a subspace of the liquid storage space and is blocked from other areas of the liquid storage space, the gas flowing into the air inlet 512 can only flow in the air filter area without The liquid storage module 500 of this embodiment has a high purification gas release rate due to free diffusion into the non-filtered gas area, resulting in the inability to discharge quickly.

By now, those skilled in the art will appreciate that, although a number of exemplary embodiments of the present invention have been shown and described in detail herein, the disclosed embodiments may still be practiced in accordance with the present invention without departing from the spirit and scope of the present invention. The content directly identifies or leads to many other variations or modifications consistent with the principles of the invention. Accordingly, the scope of the present invention should be understood and deemed to cover all such other variations or modifications.

Claims (10)

1. A refrigeration and freezing device including:

   A box whose interior defines a first storage area and a second storage area; and

   Rotating storage box, which has a plurality of storage compartments, each storage compartment defines a storage partition; and the rotating storage box is rotatably arranged, so that the storage compartments are switchably arranged at The first storage area and the second storage area.
2. The refrigeration and freezing device according to claim 1, further comprising:

   A storage container is provided in the box; and

   A separation mechanism is provided in the internal space of the storage container, and separates the internal space of the storage container into the first storage area and the second storage area; and the separation mechanism is provided with a The rotary storage box is rotatably assembled with an assembly area therein.
3. The refrigeration and freezing device according to claim 2, wherein,

   The partition mechanism is a partition structure with a board surface extending in the vertical direction, so that the first storage area and the second storage area are arranged side by side in the horizontal direction; and

   The rotating storage box is cylindrical, with a rotation axis extending in a vertical direction, and the rotation axis of the rotating storage box is coaxial with the central axis of the rotating storage box and the central axis of the assembly area.
4. The refrigeration and freezing device according to claim 3, wherein,

   The separation mechanism includes a first partition section and a second partition section that are spaced apart from each other and whose plates are coplanar; and the distance between the first partition section and the second partition section is The assembly area is formed.
5. The refrigeration and freezing device according to claim 3, wherein,

   The rotating storage box includes a disc-shaped chassis and a hollow cylindrical body extending upward from the edge of the chassis: and

   A plurality of storage compartments are formed in the barrel, and the projections of the storage compartments in a horizontal plane are centrally symmetrical with respect to the center of the chassis.
6. The refrigeration and freezing device according to claim 5, wherein,

   The rotating storage box also includes:

   a central rotating shaft extending upward from the center of the chassis; and

   A plurality of partition plates, the plate surface of each partition plate extends in the vertical direction, and extends radially outward from the outer surface of the central rotating shaft to the inner surface of the cylinder, so as to A plurality of storage compartments with top openings are spaced inside; and one storage partition is defined between every two adjacent partition boards.
7. The refrigeration and freezing device according to claim 1, wherein

   The first storage area has a vent for introducing external air to adjust the internal atmosphere using the external air; and

   Each storage compartment is provided with a ventilation opening to allow the external air to enter the storage partition through the ventilation opening when switching to the first storage area.
8. The refrigeration and freezing device according to claim 7, wherein,

   The first storage area is provided on the rear side of the second storage area; the storage container is pullably provided in the box; the back wall of the storage container is provided with a hole communicating with the second storage area. The ventilation opening of a storage area; and

   The refrigeration and freezing device further includes a gas circuit assembly, which has a ventilation pipeline connected to the ventilation port and used to transport gas to the first storage area, and the ventilation pipeline is fixed to the rear of the storage container. side; and the ventilation pipe and the ventilation port are nested with each other and detachably arranged during the pulling process of the storage container.
9. The refrigeration and freezing device according to claim 8, wherein,

   The vent is in the shape of a hollow column and protrudes outward from the back wall of the storage container; one end of the vent pipe has a hollow cylindrical interface for the vent to be nested.
10. The refrigeration and freezing device according to claim 8, further comprising:

    An oxygen treatment device is arranged in the box and has a shell and an electrode pair. The interior of the shell defines an electrochemical reaction chamber for containing electrolyte. The electrode pair is arranged in the electrochemical reaction chamber. The chamber is used to transfer external oxygen to the electrochemical reaction chamber through electrochemical reaction; the housing is provided with an exhaust hole connected to the electrochemical reaction chamber, and is used to discharge oxygen from the electrochemical reaction chamber. ;

    The first end of the air conditioning pipeline is used to communicate with the ventilation pipeline, and the second end is used to communicate with the exhaust hole.