CN218955259U - Refrigerator with a refrigerator body - Google Patents

Abstract

The application discloses a refrigerator, comprising a refrigerator body; the door body is provided with a first chute and a second chute; the hinge is connected to the box body and provided with a first shaft body and a second shaft body, and the first shaft body is positioned between the box body and the second shaft body; in the process that the door body rotates from a closed state to a first preset angle, the door body rotates by taking the second shaft body as an axis, and the first shaft body slides relative to the first sliding groove; in the process that the door body is opened from a first preset angle to a second preset angle, the door body rotates by taking the first shaft body as an axis, and the second shaft body slides relative to the second sliding groove. After the door body fixed shaft rotates to a certain angle, the other shaft is replaced to carry out fixed shaft rotation, namely, the door body carries out two sections of reducing motions in the rotation process, so that the corner part of the door body starts to adjust the rotation center of the door body when exceeding the side wall surface of the box body by a small distance, and the cabinet or the wall at the side edge of the refrigerator can be avoided.

Description

Refrigerator with a refrigerator body

Technical Field

The application belongs to the household electrical appliances field, especially relates to a refrigerator.

Background

The refrigerator is a household appliance product commonly used in daily life, and is mainly used for low-temperature fresh-keeping of fruit, vegetable, food and the like, such as freezing or refrigerating and the like.

In the related art, a refrigerator body is generally hinged to one end of a refrigerator door body, so that a user can rotate around the hinged end of the refrigerator door body to open the refrigerator body. The hinge structure of the refrigerator door body is mostly in a single-shaft form, the door body is matched with the door body through the hinge shaft to realize that the door body rotates around the hinge shaft, and the corner of the door body can exceed the side surface of the refrigerator body in the door opening process of the door body with the hinge structure. If the reserved space on the side of the refrigerator is limited, the corners of the door body can touch the side walls.

For example, for an embedded refrigerator, the refrigerator is generally placed in a cabinet, and the corner of the door body cannot exceed the side wall surface of the cabinet too much in the door opening process, otherwise, the corner of the door body can touch the cabinet at the side edge of the refrigerator in the door opening and closing process, so that the use of a user is directly affected, and the experience is poor.

Disclosure of Invention

The embodiment of the application provides a refrigerator, so that the door body cannot excessively exceed the side wall surface of the refrigerator body when being opened.

An embodiment of the present application provides a refrigerator, including:

a case;

the door body is rotationally connected with the box body and is provided with a first chute and a second chute; and

the hinge is connected to the box body and is provided with a first shaft body and a second shaft body, and the first shaft body is positioned between the box body and the second shaft body; the first shaft body is inserted into the first sliding groove, and the second shaft body is inserted into the second sliding groove;

in the process that the door body rotates to a first preset angle from a closed state, the door body can rotate by taking the second shaft body as a rotation axis, and the first shaft body can slide relative to the first sliding groove;

in the process that the door body is opened from the first preset angle to the second preset angle, the door body can rotate by taking the first shaft body as a rotation axis, and the second shaft body can slide relative to the second sliding groove.

Optionally, the first chute comprises a first positioning section and a first track section which are mutually communicated;

in the process that the door body rotates to a first preset angle from a closed state, the first shaft body slides relative to the first track section and slides to the first positioning section;

in the process that the door body is opened from the first preset angle to the second preset angle, the first shaft body can rotate relative to the first positioning section.

Optionally, the second chute comprises a second positioning section and a second track section which are mutually communicated;

when the door body is in a closed state, the second shaft body is positioned at the second positioning section, and in the process of rotating the door body from the closed state to a first preset angle, the second shaft body can rotate relative to the second positioning section;

in the process that the door body is opened from the first preset angle to the second preset angle, the second shaft body can slide relative to the second track section.

Optionally, the second chute further includes a limiting section that is connected to the second track section, the limiting section is located at an end of the second track section that is far away from the second positioning section, the door body is opened from the second preset angle to a third preset angle, the door body can rotate with the first shaft body as a rotation axis, and the second shaft body can slide relative to the second track section to abut against the limiting section.

Optionally, the first track section and the second track section are arc-shaped grooves, the first positioning section is located at the center of the second track section, and the second positioning section is located at the center of the first track section.

Optionally, the door body includes a door body rear wall surface, a door body front wall surface, and a door body side wall surface close to the hinge, where the door body rear wall surface faces the box body, the door body rear wall surface is opposite to the door body front wall surface, and the door body side wall surface is connected to the door body rear wall surface and the door body front wall surface;

when the door body is in a closed state, the distance between the axis of the second shaft body and the front wall surface of the door body is L ₁ The distance between the axis of the second shaft body and the side wall surface of the door body is L ₂ The distance between the side wall surface of the door body and the wall or the cabinet wall is L ₃ Wherein, the method comprises the steps of, wherein,

optionally, when the door body is in a closed state, a distance between an axis of the second shaft body and a front wall surface of the door body is set between 8.5 mm and 10.5 mm, and a distance between an axis of the second shaft body and a side wall surface of the door body is set between 14 mm and 17 mm.

Optionally, a center distance between the first shaft body and the second shaft body is between 9.5 mm and 12.5 mm, and when the door body is closed, the first shaft body is further away from the door body side wall surface than the second shaft body.

Optionally, when the door body is closed, an angle range of an included angle between an extension line of a connecting line between the center of the first shaft body and the center of the second shaft body and an extension surface of the side wall surface of the door body is 15 degrees to 25 degrees.

Optionally, the hinge includes a connection plate, the connection plate is connected to the box, and the first shaft body and the second shaft body are rotatably disposed on the connection plate.

According to the refrigerator, the hinge is used for realizing the hinge connection between the refrigerator body and the door body, so that the door body can rotate relative to the refrigerator body to open or close the storage compartment of the refrigerator. Through the first axis body on the hinge and the first spout on the door body mutually support to and the second axis body on the hinge and the second spout on the door body mutually support for the door body rotates to the in-process of first predetermineeing the angle from the closed condition, and the door body can rotate with the second axis body, and the first axis body can slide for first spout, and the door body is opened to the in-process of second predetermineeing the angle from first predetermineeing the angle, and the door body can rotate as the axis of rotation with the first axis body, and the second axis body can slide for the second spout. It can be understood that after the door body rotates to a certain angle, the other shaft is replaced to perform fixed-shaft rotation motion, namely, the door body performs two sections of variable-diameter motions in the rotation process, in addition, as the first shaft body is positioned between the box body and the second shaft body, in the process that the door body rotates from a closed state to a second preset angle, the rotation radius of the corner part of the door body when the second shaft body is used as the axis is smaller than that of the corner part of the door body when the first shaft body is used as the axis, and therefore, the rotation center of the door body starts to be adjusted when the corner part of the door body exceeds the side wall surface of the box body by a small distance, so that the cabinet or the wall on the side edge of the refrigerator can be avoided, and the door body moves smoothly when the door body is opened.

Drawings

The technical solution of the present application and the advantageous effects thereof will be made apparent from the following detailed description of the specific embodiments of the present application with reference to the accompanying drawings.

Fig. 1 is a schematic structural view of a refrigerator according to an embodiment of the present application.

Fig. 2 is a cross-sectional view of the refrigerator shown in fig. 1.

Fig. 3 is a schematic structural view of a hinge of the refrigerator shown in fig. 1.

Fig. 4 is a schematic structural view of a first chute and a second chute cooperating with a hinge.

Fig. 5 is an enlarged view of a portion of the structure of fig. 2 at the hinge.

Fig. 6 is a schematic structural view of the door body in the structure shown in fig. 5 when the door body is opened to a first preset angle.

Fig. 7 is a schematic structural view of the door body in the structure shown in fig. 5 when the door body is opened to a second predetermined angle.

Fig. 8 is an enlarged view at a in fig. 5.

Fig. 9 is a schematic structural view of the door body in the structure shown in fig. 5 when the door body is opened to a third preset angle.

The reference numerals in the figures are respectively:

a. a first preset angle; b. a second preset angle; c. a third preset angle;

10. a case; 11. an open end face; 12. a first sidewall; 13. a second sidewall;

20. a door body; 211. the back wall surface of the door body; 212. the front wall surface of the door body; 213. a side wall surface of the door body; 214. a first side edge;

22. a first chute; 221. a first positioning section; 222. a first track segment;

23. a second chute; 231. a second positioning section; 232. a second track segment; 233. a limiting section;

30. a hinge; 31. a first shaft body; 32. a second shaft body; 33. and (5) connecting a plate.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It will be apparent that the described embodiments are only some, but not all, of the embodiments of the present application. All other embodiments, which can be made by those skilled in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

In the description of the embodiments of the present application, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the embodiments of the present application.

Referring to fig. 1 and 2, fig. 1 is a schematic structural diagram of a refrigerator according to an embodiment of the present application, and fig. 2 is a cross-sectional view of the refrigerator shown in fig. 1. The embodiment provides a refrigerator, which may include a case 10, a door 20, and a hinge 30. The cabinet 10 is provided with a storage compartment such as a freezing compartment, a refrigerating compartment, or a wide-width variable temperature compartment. Of course, in some alternative embodiments, the storage compartment may also be some thawing compartment or sterilizing compartment with thawing function, which is not limited in this embodiment. The door 20 is used to open or close the storage compartment of the case 10. Wherein the door 20 may be hinged to the case 10 by a hinge 30. Specifically, hinges 30 may be disposed at the upper and lower portions of the case 10, and the door 20 may be smoothly rotated by being engaged with the hinge at the upper portion of the case 10 and the hinge at the lower portion of the case 10.

Wherein, the front end of the storage compartment is provided with an opening or a picking and placing opening for placing food into the storage compartment or picking food out of the storage compartment. Wherein the case 10 includes an opening end face 11 surrounding an opening of the storage compartment.

It will be appreciated that the case 10 includes oppositely disposed first and second sidewalls 12 and 13 (i.e., right and left sidewalls of the case 10). A hinge 30 is provided on the case 10 adjacent to the first side wall 12. Alternatively, the hinge 30 is disposed on the case 10 proximate to the second sidewall 13. Of course, for a two-door refrigerator, a hinge 30 is provided near both the first side wall 12 and near the second side wall 13.

The door 20 includes a door rear wall 211, a door front wall 212, and a door side wall 213 adjacent to the hinge 30, it being understood that the door rear wall 211 faces the open end face 11 of the case 10 when the door 20 is in the closed state. The door body rear wall surface 211 is disposed opposite to the door body front wall surface 212, and the door body side wall surface 213 is connected to the door body rear wall surface 211 and the door body front wall surface 212. It can be appreciated that when the hinge 30 is located on the right side of the case 10, the right side surface of the door 20 is the door side wall surface 213; when the hinge 30 is positioned on the left side of the case 10, the left side surface of the door 20 is the door side wall surface 213. The front wall 212 of the door 20 and the side wall 213 of the door intersect to form a first side edge 214, or the front wall 212 of the door and the side wall 213 of the door intersect to form a corner of the door 20. It should be noted that, when the front wall 212 of the door body and the side wall 213 of the door body are both planar, the intersection line of the two planar surfaces is the theoretical first side edge 214, and when the door body is specifically machined, a curved surface is formed at this time based on the intersection of the front wall 212 of the door body and the side wall 213 of the door body, and a vertical line extending along the length direction of the door body 20 and located in the middle of the curved surface may represent the first side edge 214.

It should be noted that, in the related art, when the door body rotates, the corner portion (or the first side edge) of the door body may exceed the side wall surface of the box body by an excessive distance, and if the box body is close to the side wall of the wall or the cabinet, the corner portion of the door body may touch the wall or the cabinet at the side edge of the refrigerator, so as to directly affect the use of the refrigerator.

Based on this, referring to fig. 3 to 7, fig. 3 is a schematic structural view of a hinge of the refrigerator shown in fig. 1, fig. 4 is a schematic structural view of a first chute and a second chute that are matched with the hinge, fig. 5 is a partially enlarged view of the structure shown in fig. 2 at the hinge, fig. 6 is a schematic structural view of the structure shown in fig. 5 when the door body is opened to a first preset angle, and fig. 7 is a schematic structural view of the structure shown in fig. 5 when the door body is opened to a second preset angle. The hinge 30 has a first shaft body 31 and a second shaft body 32, the first shaft body 31 being located between the case 10 and the second shaft body 32. Specifically, the first shaft body 31 is located between the open end face 11 of the refrigerator and the second shaft body 32, or the first shaft body 31 is closer to the open end face 11 of the refrigerator than the second shaft body 32. The door body 20 is provided with a first slide groove 22 engaged with the first shaft body 31 and a second slide groove 23 engaged with the second shaft body 32. It can be appreciated that the first shaft body 31 is inserted into the first chute 22, and the second shaft body 32 is inserted into the second chute 23. In the process of rotating the door body 20 from the closed state to the first preset angle a, the door body 20 can rotate with the second shaft body 32 as a rotation axis, and the first shaft body 31 can slide relative to the first chute 22. In the process of opening the door body 20 from the first preset angle a to the second preset angle b, the door body 20 can rotate with the first shaft body 31 as a rotation axis, and the second shaft body 32 can slide relative to the second chute 23. It will be appreciated that the first predetermined angle a is greater than the second predetermined angle b. Through the cooperation of the first shaft body 31 and the first chute 22 and the cooperation of the second shaft body 32 and the second chute 23, after the door body 20 rotates to a certain angle, the other shaft can be replaced to perform fixed-axis rotation movement, namely, the door body 20 performs two sections of variable-diameter movement in the rotation process, and because the first shaft body 31 is positioned between the box body 10 and the second shaft body 32, in the process of rotating the door body 20 from a closed state to a second preset angle b, the rotation radius of the corner part of the door body 20 when the second shaft body 32 is used as an axis is smaller than the rotation radius of the corner part of the door body 20 when the first shaft body 31 is used as an axis, so that the rotation center of the door body 20 starts to be adjusted when the corner part of the door body 20 exceeds the side wall surface of the box body 10 by a small distance (when the door body 20 rotates by using the first shaft body 31 as the rotation axis), the cabinet or the wall on the side of the refrigerator can be avoided, and the door body 20 can move smoothly when being opened.

It can be appreciated that the upper and lower ends of the refrigerator are provided with hinges 30, and the upper and lower ends of the door body 20 are provided with first and second sliding grooves 22 and 23 corresponding to the positions of the hinges 30. And the positions of the first sliding grooves 22 at the upper and lower ends of the door body 20 in the vertical direction correspond to the positions of the second sliding grooves 23 at the upper and lower ends of the door body 20 in the vertical direction, so that the movement of the upper and lower ends of the door body 20 is kept consistent, and the door body 20 is opened or closed more smoothly.

It will also be appreciated that the hinge 30 includes a connection plate 33, the connection plate 33 being secured to the cabinet 10 of the refrigerator, such as the connection plate 33 being secured to the cabinet 10 of the refrigerator by means of a screw connection. The first shaft body 31 and the second shaft body 32 are provided to the connection plate 33. Wherein, the first shaft body 31 and the second shaft body 32 are integrally formed with the connecting plate 33. The first shaft body 31 and the second shaft body 32 may be formed as separate structures with the connection plate 33, and then assembled to the connection plate 33.

It will also be appreciated that the first shaft body 31 and the second shaft body 32 are rotatably connected to the connection plate 33 in order to allow the first shaft body 31 and the second shaft body 32 to rotate or slide in the corresponding sliding grooves more smoothly.

In order to more clearly describe the mating connection relationship between the first shaft body 31 and the first chute 22, and the mating connection relationship between the second shaft body 32 and the second chute 23, the specific structures of the first shaft body 31, the first chute 22, the second shaft body 32 and the second chute 23 will be described in detail below with reference to the accompanying drawings.

Referring to fig. 4 to 7, the first chute 22 is in communication with the second chute 23, the depth of the first chute 22 is greater than that of the second chute 23, the first shaft 31 extends to the first chute 22, and the second shaft 32 extends to the second chute 23. In this way, the positions of the first runner 22 and the second runner 23 can be made relatively more compact.

The first chute 22 includes a first positioning section 221 and a first track section 222 that are mutually communicated, the first track section 222 includes a first groove wall that contacts the first shaft body 31, and the door body 20 can rotate with the second shaft body 32 as a rotation axis during the process of rotating the door body 20 from the closed state to the first preset angle a, at this time, the first shaft body 31 can slide relative to the first track section 222 and slide to the first positioning section 221. In the process of opening the door body 20 from the first preset angle a to the second preset angle b, the first shaft body 31 can rotate relative to the first positioning section 221, that is, the door body 20 can rotate with the first shaft body 31 as a rotation axis at this time, and the second shaft body 32 can slide relative to the second chute 23.

It will be appreciated that the second runner 23 includes a second positioning segment 231 and a second track segment 232 in communication with each other, the second track segment 232 including a second slot wall in contact with the second shaft 32. When the door body 20 is in the closed state, the second shaft body 32 is located at the second positioning section 231, and during the process of rotating the door body 20 from the closed state to the first preset angle a, the second shaft body 32 can rotate relative to the second positioning section 231, and at this time, the first shaft body 31 can slide relative to the first track section 222 and slide to the first positioning section 221. In the process of opening the door body 20 from the first preset angle a to the second preset angle b, the first shaft body 31 can rotate relative to the first positioning section 221, that is, the door body 20 can rotate with the first shaft body 31 as a rotation axis at this time, and the second shaft body 32 can slide relative to the second track section 232.

Thus, when the door body 20 rotates from the closed state to the first preset angle a, the second shaft body 32 rotates relatively in the second positioning section 231, the door body 20 can rotate with the second shaft body 32 as the rotation axis, the first shaft body 31 slides to the first positioning section 221 relative to the first track section 222, at this time, the door body 20 continues to rotate, the first shaft body 31 rotates relatively in the first positioning section 221 during the process of opening from the first preset angle a to the second preset angle b, and the door body 20 can rotate with the first shaft body 31 as the rotation axis, the second shaft body 32 slides relative to the second track section 232. That is, when the door body 20 rotates from the closed state to the first preset angle a, the door body 20 rotates with the second shaft body 32 as the rotation axis, and when the door body 20 rotates from the first preset angle a to the second preset angle b, the door body 20 rotates with the first shaft body 31 as the rotation axis, and the door body 20 performs two-stage reducing motion during the rotation, so that the corner of the door body 20 starts to adjust the rotation center of the door body 20 when exceeding the side wall surface of the case 10 by a small distance, so as to avoid the cabinet or the wall at the side of the refrigerator, and make the door body 20 move smoothly when opening.

Wherein, the first track section 222 and the second track section 232 are arc-shaped grooves, and the arc-shaped first track section 222 and the arc-shaped second track section 232 play a guiding role. The first positioning segment 221 is located at the center of the second track segment 232, and the second positioning segment 231 is located at the center of the first track segment 222.

It will be appreciated that please also refer to fig. 8, fig. 8 is an enlarged view of fig. 5 at a. When the door 20 is rotated from the closed state to the first predetermined angle a, that is, when the door 20 is rotated about the second shaft 32, it is required to ensure that the first side edge 214 of the door 20 (or the corner of the door 20) does not collide with the wall or the cabinet wall. Based on this, the distance between the slot center of the second positioning section 231 and the door body front wall surface 212 is denoted as L ₁ The distance between the center of the slot of the second positioning section 231 and the door side wall surface 213 is denoted as L ₂ The distance between the door side wall 213 and the wall or cabinet wall is denoted as L ₃ It will also be appreciated that the distance between the axis of the second shaft 32 and the front wall 212 of the door body is denoted as L when the door body 20 is in the closed state ₁ The distance between the axis of the second shaft body 32 and the door body side wall surface 213 is L ₂ Wherein, the method comprises the steps of, wherein,

in this way, when the door 20 rotates around the second shaft 32, the arc track moved by the first side edge 214 will not interfere with the wall or the cabinet wall.

Illustratively, for a built-in refrigerator, the distance between the side plate of the built-in cabinet and the side wall of the refrigerator is small, typically 2 mm to 4 mm. Based on this, in order to improve the adaptability, the structure of the door body 20 of the conventional refrigerator is not greatly changed, and the distance L between the center of the slot of the second positioning section 231 and the front wall surface 212 of the door body can be set ₁ A distance L between the center of the slot of the second positioning section 231 and the door body sidewall surface 213 of between 8.5 mm and 10.5 mm ₂ Between 14 mm and 17 mm. In other words, when the door 20 is in the closed state, the distance L between the axis of the second shaft 32 and the door front wall 212 ₁ Is set between 8.5 mm and 10.5 mm, and the distance L between the axis of the second shaft 32 and the side wall 213 of the door ₂ Between 14 mm and 17 mm. In this way, the arc track of the first side edge 214 can be ensured not to interfere with the wall or the cabinet wall when the door body 20 rotates around the second shaft 32 as the rotation axis without greatly changing the structure of the door body 20 of the existing refrigerator, such as without changing the thickness of the door body 20.

For example, the distance L between the center of the slot of the second positioning segment 231 and the door front wall 212 can be set ₁ Set to 9 mm, the distance L between the slot center of the second positioning section 231 and the door body side wall surface 213 ₂ Setting to 16 mm, since a rounded corner having a radius of 1 mm is generally machined at the first side edge 214 (the corner portion of the door body 20), the size of the first side edge 214 exceeding the sidewall of the case 10 during the rotation of the door body 20 can be eventually not more than 2 mm.

It can be appreciated that after the door 20 moves to the first preset angle a with the second shaft 32 as the rotation axis, the door 20 moves to the second preset angle b with the first shaft 31 as the rotation axis, so as to realize two-stage reducing movement of the door 20. Wherein, the center distance between the first shaft body 31 and the second shaft body 32 is set between 9.5 mm and 12.5 mm, and when the door 20 is in the closed state, the first shaft body 31 is farther from the door sidewall surface 213 than the second shaft body 32. Thus, when the door 20 is converted to move around the first shaft 31, the first shaft 31 is disposed at a position that prevents the arc track of the movement of the first side edge 214 from interfering with the wall or the cabinet wall during the rotation of the door 20. And when the door body 20 moves to the second preset angle b, the door body 20 does not obstruct the drawing of the drawer in the storage compartment.

As shown in fig. 5, an angle d between an extension line of a line between the center of the first shaft body 31 and the center of the second shaft body 32 and an extension surface of the door body sidewall surface 213 ranges from 15 degrees to 25 degrees, so that the door body 20 is smoother when performing two-stage reducing motion.

For ease of understanding, the following will be illustrated in connection with a specific angle of rotation of the door body 20.

For example, the first preset angle a may be 45 degrees, the second preset angle b may be 90 degrees, and of course, in other embodiments, the first preset angle a may be other angles such as 30 degrees or 35 degrees, and the second preset angle b may be other angles such as 80 degrees or 85 degrees.

In this embodiment, the first preset angle a is 45 degrees, and the second preset angle b is 90 degrees. When the door body 20 is opened from the closed state to the angle of 45 degrees, the second shaft body 32 rotates relatively in the second positioning section 231, the door body 20 can rotate with the second shaft body 32 as the rotation axis, the first shaft body 31 slides to the first positioning section 221 relative to the first track section 222, at this time, the door body 20 continues to rotate, and in the process that the door body 20 is opened from the angle of 45 degrees to the angle of 90 degrees, the first shaft body 31 rotates relatively in the first positioning section 221, at this time, the door body 20 can rotate with the first shaft body 31 as the rotation axis, and the second shaft body 32 slides relative to the second track section 232.

In some embodiments, the door 20 may be opened to a second predetermined angle b (such as 90 degrees), and the refrigerator may be placed in a position where the accommodating space is large, and it may be appreciated that when the space is large, the problem that the door 20 collides with the surrounding wall surface when the door 20 rotates to a degree greater than 90 degrees is not considered.

For example, referring to fig. 9 in combination with fig. 4, fig. 9 is a schematic structural view of the door body in the structure shown in fig. 5 when the door body is opened to a third predetermined angle. The door 20 may be opened to a third preset angle c, which is greater than the second preset angle b, such as 120 degrees. The second chute 23 may further include a limiting section 233 in communication with the second track section 232, where the limiting section 233 is located at an end of the second track section 232 away from the second positioning section 231, and in the process of opening the door body 20 from the second preset angle b to the third preset angle c, the door body 20 can rotate with the first shaft body 31 as a rotation axis, and the second shaft body 32 can slide relative to the second track section 232 to abut against a wall of the limiting section 233. Thus, the door 20 can be limited to rotate continuously by taking the first shaft 31 as the rotating shaft by the limiting function of the limiting section 233.

It is also understood that the first runner 22, which cooperates with the first shaft 31, and the second runner 23, which cooperates with the second shaft 32, may be formed directly on the door body 20. In some embodiments, the first chute 22 and the second chute 23 may be formed on the chute member, and then the chute member is mounted on the door body 20 at a position corresponding to the hinge 30, so as to form the first chute 22 and the second chute 23 at a position corresponding to the hinge 30 of the door body 20.

In the foregoing embodiments, the descriptions of the embodiments are emphasized, and for parts of one embodiment that are not described in detail, reference may be made to related descriptions of other embodiments.

The refrigerator provided by the embodiment of the present application has been described in detail, and specific examples are applied herein to illustrate the principles and embodiments of the present application, and the description of the above examples is only for helping to understand the method and core ideas of the present application; meanwhile, as those skilled in the art will vary in the specific embodiments and application scope according to the ideas of the present application, the contents of the present specification should not be construed as limiting the present application in summary.

Claims (10)

1. A refrigerator, comprising:

a case;

the door body is rotationally connected with the box body and is provided with a first chute and a second chute; and

the hinge is connected to the box body and is provided with a first shaft body and a second shaft body, and the first shaft body is positioned between the box body and the second shaft body; the first shaft body is inserted into the first sliding groove, and the second shaft body is inserted into the second sliding groove;

in the process that the door body rotates to a first preset angle from a closed state, the door body can rotate by taking the second shaft body as a rotation axis, and the first shaft body can slide relative to the first sliding groove;

in the process that the door body is opened from the first preset angle to the second preset angle, the door body can rotate by taking the first shaft body as a rotation axis, and the second shaft body can slide relative to the second sliding groove.

2. The refrigerator of claim 1, wherein the first chute comprises a first positioning section and a first track section in communication with each other;

in the process that the door body rotates to a first preset angle from a closed state, the first shaft body slides relative to the first track section and slides to the first positioning section;

in the process that the door body is opened from the first preset angle to the second preset angle, the first shaft body can rotate relative to the first positioning section.

3. The refrigerator of claim 2, wherein the second chute comprises a second positioning section and a second track section in communication with each other;

when the door body is in a closed state, the second shaft body is positioned at the second positioning section, and in the process of rotating the door body from the closed state to a first preset angle, the second shaft body can rotate relative to the second positioning section;

in the process that the door body is opened from the first preset angle to the second preset angle, the second shaft body can slide relative to the second track section.

4. The refrigerator according to claim 3, wherein the second sliding groove further comprises a limiting section communicated with the second track section, the limiting section is located at one end of the second track section away from the second positioning section, the door body can rotate with the first shaft body serving as a rotation axis in the process of opening the door body from the second preset angle to a third preset angle, and the second shaft body can slide relative to the second track section to abut against the limiting section.

5. The refrigerator of claim 3, wherein the first track section and the second track section are arc-shaped grooves, the first positioning section is located at a center of the second track section, and the second positioning section is located at a center of the first track section.

6. The refrigerator of claim 3, wherein the door body includes a door body rear wall surface, a door body front wall surface, and a door body side wall surface adjacent to the hinge, the door body rear wall surface facing the refrigerator body, the door body rear wall surface being disposed opposite the door body front wall surface, the door body side wall surface being connected to the door body rear wall surface and the door body front wall surface;

when the door body is in a closed state, the distance between the axis of the second shaft body and the front wall surface of the door body is L ₁ The distance between the axis of the second shaft body and the side wall surface of the door body is L ₂ The distance between the side wall surface of the door body and the wall or the cabinet wall is L ₃ Wherein, the method comprises the steps of, wherein,

7. the refrigerator of claim 6, wherein a distance between an axis of the second shaft and a front wall surface of the door body is set to be 8.5 mm to 10.5 mm, and a distance between an axis of the second shaft and a side wall surface of the door body is set to be 14 mm to 17 mm when the door body is in a closed state.

8. The refrigerator of claim 6, wherein a center-to-center distance between the first shaft and the second shaft is between 9.5 mm and 12.5 mm, and the first shaft is farther from the door sidewall surface than the second shaft when the door is closed.

9. The refrigerator of claim 8, wherein an angle between an extension line of a line between a center of the first shaft body and a center of the second shaft body and an extension surface of a side wall surface of the door body ranges from 15 degrees to 25 degrees when the door body is closed.

10. The refrigerator of any one of claims 1 to 9, wherein the hinge includes a connection plate connected to the case, the first shaft and the second shaft being rotatably provided to the connection plate.

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