JP2022079245A - Hinge structure of refrigerator - Google Patents

Abstract

To provide a hinge structure of a refrigerator capable of opening a door even if the refrigerator is installed close to a wall.SOLUTION: The hinge structure of a refrigerator is equipped with an upper hinge member 20 and a lower hinge member 40, first guide pins 24 and 43 and second guide pins 25 and 44 provided on the upper hinge member 20 and the lower hinge member 40, an upper guide member 30 and a lower guide member 50 attached to upper and lower sides of a door 11, and an upper guide groove 34 and a lower guide groove 54 with which the first guide pins 24 and 43 and the second guide pins 25 and 44 are engaged. The door 11 is opened/closed by regulating the upper guide groove 34 and the lower guide groove 54 with the first guide pins 24 and 43 and the second guide pins 25 and 44. A virtual rotation center O when the door 11 of the first guide pins 24 and 43 and the second guide pins 25 and 44 is opened/closed, is located on a front surface side from the door 11 while the door 11 is closed.SELECTED DRAWING: Figure 3

Description

The present disclosure relates to a hinge structure of a refrigerator.

Patent Document 1 discloses a hinge structure of a refrigerator. In this hinge structure, the door is provided with a guide block, the hinge body is provided with a rotation shaft, the guide block is provided with a rotation shaft groove, and the structure of the hinge body causes the gravity and frictional force of the door to be the first of the hinge body. It is distributed to the plate body and the second plate body of the above, and can reduce the wear and extend the service life of the refrigerator door.

Special Table 2020-521102

The present disclosure provides a hinge structure for a refrigerator that allows the door to be opened even when the refrigerator is installed close to a wall.

The hinge structure of the refrigerator in the present disclosure is a hinge structure of a refrigerator that supports the main body of the door so as to be openable and closable. The door is provided with a guide pin of 2, a guide member attached to the upper and lower sides of the door, and a guide groove provided on the guide member to which the first guide pin and the second guide pin are engaged. Is a virtual operation when the guide groove is restricted by the first guide pin and the second guide pin to open and close, and the door of the first guide pin and the second guide pin is opened and closed. The center of rotation is characterized in that it is located on the front side of the door with the door closed.

The hinge structure of the refrigerator in the present disclosure allows the door to be opened even when the refrigerator is installed close to the wall when the door is opened.

A perspective view showing the refrigerator of the first embodiment. An exploded perspective view showing the hinge structure of the refrigerator according to the first embodiment. A perspective view showing the upper hinge structure of the first embodiment. An exploded perspective view showing the upper hinge structure of the first embodiment. A perspective view showing the lower hinge structure of the first embodiment. An exploded perspective view showing the lower guide structure of the first embodiment. Explanatory drawing which shows operation of the upper guide groove and the upper guide pin of Embodiment 1. Explanatory drawing which shows operation of the lower guide groove and the lower guide pin of Embodiment 1. An exploded perspective view showing the lower guide structure of the second embodiment. Perspective view of the lower hinge member of the second embodiment Explanatory drawing which shows operation of the lower guide groove and the lower guide pin of Embodiment 2.

(Findings, etc. that form the basis of this disclosure)
If the refrigerator is installed close to the wall of the installation location and the center of rotation by the axis of rotation is inside the door, when the door is opened, the front corner of the door will protrude to the side from the main body of the refrigerator. The inventors have discovered the problem of being unable to open the door, and in order to solve the problem, they have constructed the subject matter of the present disclosure.
Therefore, the present disclosure provides a hinge structure of a refrigerator capable of opening the door even when the refrigerator is installed close to the wall.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, more detailed explanation than necessary may be omitted. For example, detailed explanations of already well-known matters or duplicate explanations for substantially the same configuration may be omitted. This is to prevent the following explanation from becoming unnecessarily redundant and to facilitate the understanding of those skilled in the art.
It should be noted that the accompanying drawings and the following description are provided for those skilled in the art to fully understand the present disclosure, and are not intended to limit the subject matter described in the claims.

(Embodiment 1)
Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 7.
[1-1. Constitution]
[1-1-1. Refrigerator configuration]
FIG. 1 is a perspective view showing an outline of a refrigerator to which the hinge structure according to the present invention is applied. FIG. 2 is an exploded perspective view of a hinge structure portion showing an outline of a refrigerator.
As shown in FIG. 1, the refrigerator 1 includes a box-shaped main body 10. A door 11 is provided on the front surface of the main body 10 by a hinge structure 12 so as to be openable and closable. In the present embodiment, the door 11 is composed of two doors 11, each of which is attached so as to be double doorable.

[1-1-1. Configuration of hinge structure 12]
FIG. 3 is a perspective view showing the upper hinge structure 12. FIG. 4 is an exploded perspective view showing the upper hinge structure 12. FIG. 5 is a perspective view showing the lower hinge structure 12. FIG. 6 is an exploded perspective view showing the lower hinge structure 12.
Since the hinge structure 12 of the door 11 is symmetrical, only the hinge structure 12 of the door 11 located on the right side when viewed from the front will be described below.

As shown in FIGS. 3 and 4, flat plate-shaped upper hinge members 20 are attached to the upper portions on both sides of the main body 10.
The upper hinge member 20 has a base portion 21 fixed to the main body 10, a pin support portion 22 extending from the front end portion of the base portion 21 to a position overlapping the upper portion of the door 11, and a side side of the main body 10 on the end side. It is provided with a hinged upper notch 23.
A first upper guide pin 24 and a second upper guide pin 25 are provided on the lower surface of the pin support portion 22 so as to project downward. The first upper guide pin 24 and the second upper guide pin 25 are arranged at a predetermined interval, and connect the center of the first upper guide pin 24 and the center of the second upper guide pin 25. The lines are arranged so as to be inclined so as to have a predetermined angle with respect to the front surface of the door 11.

An upper hinge mounting recess 13 is formed on one upper side of the door 11 so as to cut out a part of one side surface side of the door 11 and a rear surface side. As a result, the upper cover wall 14 is formed on the front side of the door 11. An opening 15 is formed in the upper hinge mounting recess 13 of the door 11.
An upper guide member 30 is attached to the upper hinge mounting recess 13 so as to close the opening 15.
More specifically, the door 11 has a front plate 11a forming the front surface, a door cap 11b forming the outer frame of the front plate 11a, an inner plate 11c, and a heat insulating material (illustrated) surrounded by these. The upper hinge mounting recess 13 is formed by notching the side surface side and the rear surface side of the door cap 11b on the upper one side of the door 11, and is formed in the upper hinge mounting recess 13. The upper guide member 30 is attached so as to close the opening 15.

The upper guide member 30 includes a flat plate portion 31 that closes the opening 15, an upper guide recess 32 that projects toward the lower surface side of the flat plate portion 31, and a positioning portion 33 formed at a corner portion of the flat plate portion 31. The upper guide member 30 is fixed to the door 11 by screwing a screw (not shown) into the door 11 via the positioning portion 33.
Further, the upper guide recess 32 has a bottom surface portion 32a, and is formed so that the heat insulating material does not enter the upper guide recess 32 by the bottom surface portion 32a when the door 11 is filled with a heat insulating material (not shown). ing.
Further, as described above, the upper guide member 30 is formed separately from the cap 11b, but may be integrally formed.

An upper guide groove 34 that opens into the flat plate portion 31 is formed inside the upper guide recess 32. In the present embodiment, the upper guide groove 34 has a radius of curvature from the first upper guide portion 35 formed in an arc shape extending from the front side of the door 11 toward the rear and the first upper guide portion 35. A second upper guide portion 36 formed in a small arc shape and a third arc-shaped upper guide portion 37 connected to the rear of the second upper guide portion 36 are provided. As a result, the upper guide groove 34 is formed in a substantially J shape in a plan view.
Further, the opening of the upper guide groove 34 is provided with a rib-shaped protrusion 38 formed upward from the flat plate portion 31 and is formed on the entire circumference of the upper guide groove 34.
The first upper guide pin 24 and the second upper guide pin 25 are engaged with the upper guide groove 34, and the rib-shaped protrusion 38 when opening and closing the door 11 slides on the upper hinge member 20. It has become.
When the door 11 is opened from the closed state, a first upper guide portion 35 is formed in order to prevent the door 11 from popping out toward the side wall of the installation location, and a second door 11 can be opened up to 90 degrees. The upper guide portion 36 is formed.
Further, in order to open the opening angle of the door 11 by 90 ° or more, specifically about 120 °, a third upper guide portion 37 in which the second upper guide pin 25 is located is formed.

As shown in FIGS. 5 and 6, lower hinge members 40 are attached to the lower portions on both sides of the main body 10.
The lower hinge member 40 includes a flat plate-shaped base 41, a flange 42 extending downward from the rear end of the base 41, and a lower notch 45.
The lower hinge member 40 is fixed to the main body 10 by tightening the flange portion 42 to the front surface of the main body 10 with screws or the like.
The base 41 of the lower hinge member 40 is provided with a first lower guide pin 43 and a second lower guide pin 44 so as to project upward. The first lower guide pin 43 and the second lower guide pin 44 are provided at positions overlapping the first upper guide pin 24 and the second upper guide pin 25 in a plan view.

A lower hinge mounting recess 16 is formed on one lower side of the door 11 so as to cut out one side and the rear surface side of the door 11. As a result, the lower cover wall 17 is formed on the front side of the door 11.
A lower opening (not shown) is formed in the lower hinge mounting recess 16 of the door 11. A lower guide member 50 is attached to the lower hinge mounting recess 16 so as to close the lower opening.
The lower guide member 50 includes a flat plate portion 51 that closes the lower opening, a lower guide recess 52 that projects toward the upper surface side of the flat plate portion 51, and a positioning portion 53 formed at a corner portion of the flat plate portion 51. The lower guide member 50 is fixed to the door 11 via a positioning portion 53 with a screw or the like (not shown).

More specifically, similarly to the upper guide member 30, a lower hinge mounting recess 16 is formed so as to cut out the side surface side and the rear surface side of the door cap 11b on the lower one side of the door 11, and the lower hinge mounting recess 16 is formed. The lower guide member 50 is attached so as to close the lower opening (not shown) formed in 16.
Further, the lower guide recess 52 has a bottom surface portion 52a, and is formed so that the heat insulating material does not enter the lower guide recess 52 by the bottom surface portion 52a when the door 11 is filled with the heat insulating material (not shown). Has been done.
Further, as described above, the lower guide member 50 is formed separately from the cap 11b, but may be integrally formed.

A lower guide groove 54 that opens into the flat plate portion 51 is formed inside the lower guide recess 52. In the present embodiment, the lower guide groove 54 has a smaller radius of curvature than the first lower guide portion 55 extending in an arc shape from the front side of the door 11 toward the rear and the first lower guide portion 55. A second lower guide portion 55 formed in an arc shape and a third lower guide portion 57 in an arc shape connected to the rear of the second lower guide portion 56 are provided. As a result, the lower guide groove 54 is formed in a substantially J shape in a plan view, and the lower guide groove 54 is formed at a position overlapping the upper guide groove 34 in a plan view.
Further, the opening of the lower guide groove 54 is provided with a rib-shaped protrusion 58 formed downward from the flat plate portion 51, and is formed on the entire circumference of the lower guide groove 54.
Further, a first flange portion 43a and a second flange portion 44a are formed so as to project from the bases of the first lower guide pin 43 and the second lower guide pin 44 to the entire circumference of the guide pin.
A first lower guide pin 43 and a second lower guide pin 44 are engaged with the lower guide groove 54, and a rib-shaped protrusion 58 formed on the entire circumference of the opening of the lower guide groove 54 is first. It is configured to slide with the first flange portion 43a of the lower guide pin 43 and the second flange portion 44a of the second lower guide pin 44.

[1-2. motion]
The operation of the hinge structure 12 of the refrigerator 1 configured as described above will be described below.
FIG. 7 is an explanatory diagram showing the operation of the upper guide groove 34 and the upper guide pins 24 and 25.
FIG. 7A shows a state in which the door 11 is closed. In this state, the first upper guide pin 24 is located at the front end of the upper guide groove 34, and the second upper guide pin 25 is located behind the upper guide groove 34.
At this time, the virtual rotation center O is located on the front side of the door 11 and on one side of the door 11.

Here, the virtual rotation center O is an intersection of perpendicular lines with respect to the upper guide groove 34 at the position of the first upper guide pin 24 and the position of the second upper guide pin 25.
In the case of FIG. 7A, when the door 11 is opened while the virtual rotation center O is located on one side of the door 11 on the front side of the front plate 11a of the door 11, the door 11 is opened. Is started to open around the virtual rotation center O.

Generally, when the door 11 is opened and closed on one axis, the door 11 rotates without moving around the one axis, so that the front corner portion 11d of the door 11 located in front of this axis is the main body. It sticks out from the side of 10. Therefore, if the refrigerator 1 is installed in close contact with the wall, the door 11 cannot be opened.
However, in the present embodiment, since the virtual rotation center O is located on the front side of the front plate 11a of the door 11 and on one side of the door 11, when the door 11 is opened, the door 11 is opened. The front side corner portion 11d of the main body 10 does not protrude from the side surface of the main body 10. This makes it possible to open the door 11 even when the refrigerator 1 is installed close to the wall.

As shown in FIG. 7B, when the door 11 is further opened, the first upper guide pin 24 is located in the middle of the first upper guide portion 35 of the upper guide groove 34, and the second upper part is located. The guide pin 25 is located at the second upper guide portion 36 of the upper guide groove 34.
The virtual rotation center O at this time is substantially in front of the door 11 and is located inside from one side of the door 11. In this way, as the door 11 is opened, the positional relationship between the first upper guide pin 24 and the second upper guide pin 25 and the upper guide groove 34 changes. The position also moves toward the inside of the door 11.

When the door 11 is opened by about 90 °, as shown in FIG. 7 (c), the first upper guide pin 24 is located at the second upper guide portion 36 of the upper guide groove 34, and the second upper part is located. The guide pin 25 is located at the third upper guide portion 37 of the upper guide groove 34.
The virtual rotation center O at this time is further located inside from one side of the door 11, but since the door 11 is in the open state, one side corner (front side corner) 11d of the door 11 Does not protrude to the side of the main body 10.

As shown in FIG. 7 (d), in the present embodiment, the door 11 can be further opened up to about 120 °, and in this state, the first upper guide pin 24 is referred to as FIG. 7 (c). The second upper guide pin 25 is located at substantially the same location, and the second upper guide pin 25 is located at the innermost part of the third upper guide portion 37 of the upper guide groove 34.
The virtual rotation center O at this time coincides with the first upper guide pin 24.

As described above, in the present embodiment, the first upper guide portion 35 is formed in the shape of an arc having a large radius of curvature, the second upper guide portion 36 is formed in the shape of an arc having a small radius of curvature, and the third is further formed. By forming the upper guide portion 37 of the door 11, the door 11 can be opened and closed while the virtual rotation center O is moved.
When the door 11 is opened, the end of the upper cover wall 14 of the door 11 is located at the upper notch 23 of the upper hinge member 20, so that the door 11 hits the upper hinge member 20. There is no.

Further, due to the weight of the door 11 and the storage of food in the door 11, a large load is particularly applied to the lower hinge member 40. Even in such a case, the rib-shaped protrusion 58 of the lower guide groove 54 slides on the first flange portion 43a of the first lower guide pin 43 and the second flange portion 44a of the second lower guide pin 44. Since the door 11 is opened and closed, the frictional force at the time of opening and closing is reduced, and the user's door opening force can be reduced.
In the case of the present embodiment, the radius of curvature of the third upper guide portion 37 is larger than the radius of curvature of the second upper guide portion 36 and smaller than the radius of curvature of the first upper guide portion 35. ..
Further, the magnitude relation of the radius of curvature of each of the first upper guide portion 35, the second upper guide portion 36, and the third upper guide portion 37 is the wall thickness of the door 11, that is, the thickness of the door cap 11b (FIG. 7). If the thickness of the door cap 11b is large, the radius of curvature of the second upper guide portion 36 can be increased to approach the radius of curvature of the first upper guide portion 35. ..

Further, by increasing the thickness of the door cap 11b, the radius of curvature of the first upper guide portion 35 and the second upper guide portion 36 can be made the same, and the virtual rotation center O is also on the same side. The upper guide portion 35 and the second upper guide portion 36 can be used as one upper guide portion, and the upper guide groove 34 can be formed by the third upper guide portion 37 connected to the upper guide portion 35. ..
Therefore, since the upper guide groove 34 is formed by the two upper guide portions having different radii of curvature, the door 11 can be rotated more smoothly.

Further, although the second upper guide portion 36 has an arc shape, it may have a curved shape, and if the door cap 11b has a large thickness, it may be formed by connecting a plurality of linear shapes.
Further, the first upper guide portion 35 may be formed in a linear shape, and the second upper guide portion 36 and the third upper guide portion 37 may be formed in an arc shape.
Further, in FIG. 7, the upper guide groove 34 is formed by three arc-shaped guide portions having different radii of curvature, but may be formed by four or more different arc-shaped guide portions.
Thereby, the upper guide groove 34 can be formed even when the thickness of the door cap 11b is small.
Therefore, the upper guide groove 34 can be formed regardless of the thickness of the door cap 11b, and the door 11 can be smoothly opened even when the refrigerator 1 is installed close to the wall. ..

Next, the operation of the lower guide groove 54 and the lower guide pins 43 and 44 will be described.
FIG. 8 is an explanatory diagram showing the relationship between the lower guide groove 54 and the lower guide pins 43 and 44.
FIG. 8A shows a state in which the door 11 is closed. In this state, the first lower guide pin 43 is located at the front end of the lower guide groove 54, and the second lower guide pin 44 is located behind the lower guide groove 54.
At this time, the virtual rotation center O is located on the front side of the door 11 and on one side of the door 11.
Here, the virtual rotation center O is an intersection of perpendicular lines with respect to the lower guide groove 54 at the position of the first lower guide pin 43 and the position of the second lower guide pin 44.

In the case of FIG. 8A, when the door 11 is opened while the virtual rotation center O is located on the front side of the front plate 11a of the door 11 and on one side of the door 11, the door 11 is opened. Is started to open around the virtual rotation center O.
The door 11 regardless of whether the lower guide groove 54 and the lower guide pins 43, 44 or the refrigerator 1 is installed close to the wall, as in the case of the upper guide groove 34 and the upper guide pins 24, 25. Can be opened.

As shown in FIG. 8B, when the door 11 is further opened, the first lower guide pin 43 is located in the middle of the first lower guide portion 55 of the lower guide groove 54, and the second lower part is located. The guide pin 44 is located at the second lower guide portion 56 of the lower guide groove 54.
The virtual rotation center O at this time is substantially in front of the door 11 and is located inside from one side of the door 11. In this way, as the door 11 is opened, the positional relationship between the first lower guide pin 43 and the second lower guide pin 44 and the lower guide groove 54 changes, and accordingly, the virtual rotation center O of the virtual rotation center O. The position also moves toward the inside of the door 11.

When the door 11 is opened by about 90 °, as shown in FIG. 8C, the first lower guide pin 43 is located at the second lower guide portion 56 of the lower guide groove 54, and the second lower part is located. The guide pin 44 is located at the third lower guide portion 57 of the lower guide groove 54.
The virtual rotation center O at this time is further located inside from one side portion of the door 11, but since the door 11 is in the open state, the one side corner portion 11d of the door 11 does not protrude.

As shown in FIG. 8 (d), in the present embodiment, the door 11 can be further opened up to about 120 °, and in this state, the first lower guide pin 43 is referred to as FIG. 8 (c). The second lower guide pin 44 is located at substantially the same location, and the second lower guide pin 44 is located at the innermost part of the third lower guide portion 57 of the lower guide groove 54.
The virtual rotation center O at this time coincides with the first lower guide pin 43.

As described above, even in the case of the lower guide groove 54 and the lower guide pins 43, 44, the first lower guide portion 55 has a large radius of curvature as in the case of the upper guide groove 34 and the upper guide pins 24, 25. By forming the second lower guide portion 56 into an arc shape, forming the second lower guide portion 56 into an arc shape having a small radius of curvature, and further forming the third upper guide portion 37 into an arc shape, the virtual rotation center O is moved while moving. The door 11 can be opened and closed.
When the door 11 is opened, the end of the lower cover wall 17 of the door 11 is located at the lower notch 45 of the lower hinge member 40, so that the door 11 hits the lower hinge member 40. There is no.

Further, in the case of the present embodiment, when the lower guide portion is described, the radius of curvature of the third lower guide portion 57 is larger than the radius of curvature of the second lower guide portion 56, and the first lower guide portion 55 It is configured to be smaller than the radius of curvature.
Further, the magnitude relation of the radius of curvature of each of the first lower guide portion 55, the second lower guide portion 56, and the third lower guide portion 57 is the wall thickness of the door 11, that is, the thickness of the door cap 11b (FIG. It can be changed by the vertical direction of the paper surface of 8), and if the thickness of the door cap 11b is large, the radius of curvature of the second lower guide portion 56 can be increased to bring it closer to the radius of curvature of the first lower guide portion 55. can.

Further, by increasing the thickness of the door cap 11b, the radius of curvature of the first lower guide portion 55 and the second lower guide portion 56 can be made the same, and the virtual rotation center O is also on the same side. The lower guide portion 55 and the second lower guide portion 56 can be one lower guide portion, and the lower guide groove 54 can be formed by the third lower guide portion 57 connected to the lower guide portion 55. ..
Therefore, since the lower guide groove 54 is formed by the two lower guide portions having different radii of curvature, the door 11 can be rotated more smoothly.

Further, although the second lower guide portion 56 has an arc shape, it may have a curved shape, and if the door cap 11b has a large thickness, it may be formed by connecting a plurality of linear shapes.
Further, the first lower guide portion 55 may be formed in a linear shape, and the second lower guide portion 56 and the third lower guide portion 57 may be formed in an arc shape.
Further, in FIG. 8, the lower guide groove 54 is formed by three arc-shaped guide portions having different radii of curvature, but may be formed by four or more different arc-shaped guide portions.
Thereby, the lower guide groove 54 can be formed even when the thickness of the door cap 11b is small.
Therefore, the lower guide groove 54 can be formed regardless of the thickness of the door cap 11b, and the door 11 can be smoothly opened even when the refrigerator 1 is installed close to the wall. ..
As described above, the lower guide portion has been described, but the upper guide portion is also formed in the same manner.

[1-3. Effect, etc.]
As described above, in the present embodiment, the upper hinge member 20 and the lower hinge member 40 (hinge members) attached to the upper and lower parts of the main body 10 and the first first provided on the upper hinge member 20 and the lower hinge member 40. The guide pins 24, 43 and the second guide pins 25, 44, the upper guide member 30 and the lower guide member 50 (guide member) attached to the upper and lower sides of the door 11, and the upper guide member 30 and the lower guide member 50 are provided. The door 11 comprises an upper guide groove 34 and a lower guide groove 54 (guide groove) to which the first guide pins 24, 43 and the second guide pins 25, 44 are engaged, and the door 11 has the upper guide groove 34 and the upper guide groove 34 and the lower guide groove 54 (guide groove). The lower guide groove 54 is restricted by the first guide pins 24, 43 and the second guide pins 25, 44 to open and close, and the door 11 of the first guide pins 24, 43 and the second guide pins 25, 44 The virtual rotation center O when the door 11 opens and closes is located on the front side of the door 11 with the door 11 closed.

As a result, the virtual rotation center O when the doors 11 of the first guide pins 24 and 43 and the second guide pins 25 and 44 open and close is located on the front side of the door 11 with the door 11 closed. Therefore, when the door 11 is opened, it is possible to prevent the front corner portion 11d of the door 11 from protruding to the side of the main body 10. Therefore, even when the refrigerator 1 is installed close to the wall, the door 11 can be opened.

Further, in the present embodiment, the upper guide groove 34 and the lower guide groove 54 (guide groove) are provided with at least two guide portions formed in an arc shape, and one that regulates while moving the virtual rotation center O. It is composed of a guide groove.

As a result, the door 11 is rotated while the two guide pins are located in one guide groove connecting at least two arcuate guide portions, and the door 11 is opened and closed while the virtual rotation center O is moved. Can perform actions. Therefore, since the virtual rotation center O when the door 11 opens and closes is located on the front side of the door 11 with the door 11 closed in one guide groove, the refrigerator 1 is installed close to the side wall. Even if this is the case, the door 11 can be opened.

Further, in the present embodiment, the front side of the upper hinge member 20, the lower hinge member 40 (hinge member), the upper guide member 30, and the lower guide member 50 (guide member) provided in the main body 10 is the door of the door 11. An upper cover wall 14 and a lower cover wall 17 (cover wall) are formed in front of the eleven to cover the upper cover wall 14 so as not to be seen when the user stands.

As a result, the upper cover wall 14 and the lower cover wall 17 cover the front side of the upper hinge member 20, the lower hinge member 40, the upper guide member 30, and the lower guide member 50 so as not to be seen from the front of the door 11. Can be hidden. Therefore, the upper hinge member 20, the lower hinge member 40, the upper guide member 30, and the lower guide member 50 cannot be seen from the front side of the door 11, and the appearance can be improved.

Further, in the present embodiment, the upper hinge member 20 and the lower hinge member 40 (hinge member) receive the ends of the upper cover wall 14 and the lower cover wall 17 (cover wall) when the door 11 is opened. The upper notch 23 and the lower notch 45 (notch) are formed.
As a result, when the door 11 is opened, the ends of the upper cover wall 14 and the lower cover wall 17 enter the upper notch 23 and the lower notch 45. Therefore, the door 11 can be smoothly opened.

(Embodiment 2)
[2-1. Constitution]
Next, in the second embodiment of the present invention, a configuration in which the lower guide member 60 and the latch portion 69 having a stopper function are integrally formed will be described.
The relationship between the upper guide member and the upper hinge member and the configuration in which the hinge member is hidden by a cover so as not to be seen from the front are the same as those in the first embodiment, and the description thereof will be omitted.
As shown in FIGS. 9 and 10, a lower hinge member 70 is attached to the lower part of the door 11.
Further, a stopper 80 that abuts on the lower hinge member 70 and restricts the opening of the door 11 is attached to the lower portion of the door 11.

The lower hinge member 70 includes a flat plate-shaped base 71, a flange portion 72 extending downward from the rear end of the base 71, a lower notch portion 75, and a latch portion 69 integrally formed with a lower guide member 60 described later. It is provided with a latch locking portion 76 for locking the above.
The lower hinge member 70 is fixed to the main body 10 by tightening the flange portion 72 to the front surface of the main body 10 with a screw or the like.
The base 71 of the lower hinge member 70 is provided with a first lower guide pin 73 and a second lower guide pin 74 so as to project upward. The first lower guide pin 73 and the second lower guide pin 74 are provided at positions overlapping the first upper guide pin 24 and the second upper guide pin 25 described in the first embodiment in a plan view. ing.
Further, a first flange portion 73a and a second flange portion 74a are formed so as to project from the bases of the first lower guide pin 73 and the second lower guide pin 74 to the entire circumference of the guide pin. ..

Further, in FIG. 9, a step accommodating portion 11e is formed in the cap 11b of the door 11 to accommodate the flat plate portion 61 and the lower guide recess 62 of the lower guide member 60, and the shape of the step accommodating portion 11e is the lower portion. The guide member 60 is positioned.
The lower guide member 60 includes a flat plate portion 61, a lower guide recess 62 protruding toward the upper surface side of the flat plate portion 61, a fixing portion 63 fixed to the step storage portion 11e of the cap 11b with a screw or the like, and a latch portion 69 for a stopper. Is integrally molded.
The lower guide member 60 and the stopper 80 are vertically overlapped and fixed to the step storage portion 11e via the fixing portion 63.

Further, in FIG. 11, a lower guide groove 64 that opens into the flat plate portion 61 is formed inside the lower guide recess 62. In the present embodiment, the lower guide groove 64 has a smaller radius of curvature than the first lower guide portion 65 extending in an arc shape from the front side of the door 11 toward the rear and the first lower guide portion 65. A second lower guide portion 66 formed in an arc shape and a third lower guide portion 67 in an arc shape connected to the rear of the second lower guide portion 66 are provided.
As a result, the lower guide groove 64 is formed in a substantially J-shape in a plan view, and the lower guide groove 64 is formed at a position overlapping the upper guide groove 34 described in the first embodiment in a plan view. ing.

Further, the opening of the lower guide groove 64 is provided with a rib-shaped protrusion 68 formed downward from the flat plate portion 61, and is formed on the entire circumference of the lower guide groove 64.
The first lower guide pin 73 and the second lower guide pin 74 are engaged with the lower guide groove 64, and the rib-shaped protrusion 68 formed on the entire circumference of the opening of the lower guide groove 64 is the first. It is configured to slide with the first flange portion 73a of the lower guide pin 73 and the second flange portion 74a of the second lower guide pin 74.

[2-2. motion]
Next, the operation of the lower guide groove 64 and the lower guide pins 73, 74 will be described.
FIG. 11 is an explanatory diagram showing the relationship between the lower guide groove 64 and the lower guide pins 73 and 74.
FIG. 11A shows a state in which the door 11 is closed. In this state, the first lower guide pin 73 is located at the front end of the lower guide groove 64, and the second lower guide pin 74 is located behind the lower guide groove 64.
At this time, the virtual rotation center O is located on the front side of the door 11 and on one side of the door 11.

Here, the virtual rotation center O is an intersection of perpendicular lines with respect to the lower guide groove 64 at the position of the first lower guide pin 73 and the position of the second lower guide pin 74.
In the case of FIG. 11A, when the door 11 is opened while the virtual rotation center O is located on one side of the door 11 on the front side of the front plate 11a of the door 11, the door 11 is opened. Is started to open around the virtual rotation center O.
Both the lower guide pins 73 and 74 are located in the first lower guide portion 65.

Further, in the state where the door 11 of FIG. 11A is closed, the latch portion 69 maintains the state of being engaged with the latch locking portion 76 and constitutes a stopper action so that the door 11 does not open. Further, the state in which the door 11 and the main body 10 are sealed with the gasket 90 can be maintained.
Even in the case of the lower guide groove 64 and the lower guide pins 73 and 74, when the refrigerator 1 is installed close to the wall as in the case of the lower guide groove 54 and the lower guide pins 43 and 44 of the first embodiment. However, it is possible to open the door 11.

As shown in FIG. 11B, when the door 11 is further opened, the latch portion 69 is disengaged from the latch locking portion 76, and the first lower guide pin 73 is the first lower guide of the lower guide groove 64. The second lower guide pin 74 is located in the middle of the portion 65, and the second lower guide pin 74 is located in the second lower guide portion 66 of the lower guide groove 64.
The virtual rotation center O at this time is substantially in front of the door 11 and is located inside from one side of the door 11. In this way, as the door 11 is opened, the positional relationship between the first lower guide pin 73 and the second lower guide pin 74 and the lower guide groove 64 changes. The position also moves toward the inside of the door 11.

When the door 11 is opened by about 90 °, as shown in FIG. 11C, the first lower guide pin 73 is located at the second lower guide portion 66 of the lower guide groove 64, and the second lower part is located. The guide pin 74 is located at the third lower guide portion 67 of the lower guide groove 64.
The virtual rotation center O at this time is further located inside from one side portion of the door 11, but since the door 11 is in the open state, the one side corner portion 11d of the door 11 does not protrude.

As shown in FIG. 11D, in the present embodiment, when the door 11 is opened from the closed state to 120 °, the stopper 80 hits the stopper contact portion 75 of the lower hinge member 70 and the door 11 is opened. Is restricted. In this state, the first lower guide pin 73 is located at substantially the same position as in FIG. 11 (c), and the second lower guide pin 74 is the most of the third lower guide portion 57 of the lower guide groove 64. Located in the back.
The virtual rotation center O at this time coincides with the first lower guide pin 73.

As described above, even in the case of the lower guide groove 64 and the lower guide pins 73, 74, the first lower guide portion 65 is provided as in the case of the lower guide groove 54 and the lower guide pins 43, 44 of the first embodiment. The virtual rotation center O is formed by forming the second lower guide portion 66 into an arc shape having a large radius of curvature, forming the second lower guide portion 66 into an arc shape having a small radius of curvature, and further forming the third lower guide portion 67 into an arc shape. The door 11 can be opened and closed while being moved.
When the door 11 is opened, the stopper 80 hits the stopper contact portion 75 and the opening of the door 11 is restricted so as not to open more than 120 degrees, so that the end portion of the door 11 may hit the lower hinge member 70. do not have.

[2-3. Effect, etc.]
As described above, also in the present embodiment, the door is the virtual rotation center O when the door 11 of the first lower guide pin and the second lower guide pin is opened and closed, as in the first embodiment. Can be positioned on the front side of the door 11 in the closed state, and prevents the front corner portion 11d of the door 11 from protruding to the side of the main body 10 when the door 11 is opened. Can be done. Therefore, even when the refrigerator 1 is installed close to the wall, the door 11 can be opened.

Further, the upper guide groove 34 and the lower guide groove 64 (guide groove) are provided with at least two guide portions formed in an arc shape, and are composed of one guide groove that regulates while moving the virtual rotation center O. ..
As a result, the door 11 is rotated while the two guide pins are located in one guide groove connecting at least two arcuate guide portions, and the door 11 is opened and closed while the virtual rotation center O is moved. Can perform actions. Therefore, since the virtual rotation center O when the door 11 opens and closes is located on the front side of the door 11 with the door 11 closed in one guide groove, the refrigerator 1 is installed close to the side wall. Even if this is the case, the door 11 can be opened.

Further, since the lower guide member 60 is integrally formed with a latch portion 69 for a stopper that can be engaged with the lower hinge member 70, the closed state of the door 11 can be maintained.
Further, it has a stopper 80 that abuts on the lower hinge member 70 to limit the opening of the door 11, and the stopper 80 is attached to the lower part of the door 11 together with the lower guide member 60. Therefore, the opening angle of the door 11 can be limited, and the mounting workability of the stopper 80 can be improved.
In the above embodiments 1 and 2, the double-door refrigerator is shown, but the door of the single-door refrigerator is provided with the same upper hinge member and upper guide member, and the lower hinge member and lower guide member. Even if there is, it has the same effect.

As described above, the first to second embodiments have been described as examples of the techniques disclosed in the present application. However, the technique in the present disclosure is not limited to this, and can be applied to embodiments in which changes, replacements, additions, omissions, etc. have been made. Further, it is also possible to combine the components described in the first to second embodiments to form a new embodiment.

The present disclosure is applicable to refrigerators, microwave ovens, and other home appliances that can open and close doors even when they are installed close to a wall in a room.

1 Refrigerator 10 Main body 11 Door 11a Front plate 11b Door cap 11c Inner plate 11d Front side corner 11e Step storage 12 Hinge structure 13 Upper hinge mounting recess 14 Upper cover wall 16 Lower hinge mounting recess 17 Lower cover wall 20 Upper hinge member 23 Upper notch 24 1st upper guide pin 25 2nd upper guide pin 30 Upper guide member 31 Flat plate 32 Upper guide recess 34 Upper guide groove 34a 1st upper guide groove 34b 2nd upper guide groove 35 1st Upper guide part 36 Second upper guide part 37 Third upper guide part 40 Lower hinge member 41 Base 42 Flange part 43 First lower guide pin 44 Second lower guide pin 45 Lower notch 50 Lower guide member 51 Flat plate part 52 Lower guide recess 53 Positioning part 54 Lower guide groove 55 First lower guide part 56 Second lower guide part 57 Curved part O Virtual rotation center

Claims (6)

In the hinge structure of the refrigerator that supports the door to open and close freely with respect to the main body
Hinge members attached to the top and bottom of the main body and
The first guide pin and the second guide pin provided on the hinge member,
The guide members attached to the top and bottom of the door and
The guide member is provided with a guide groove to which the first guide pin and the second guide pin are engaged.
The door is opened and closed with the guide groove restricted by the first guide pin and the second guide pin.
The virtual rotation center of the first guide pin and the second guide pin when the door is opened / closed is characterized in that the virtual rotation center is located on the front side of the door in a closed state. Refrigerator hinge structure. The refrigerator according to claim 1, wherein the guide groove includes at least two guide portions formed in an arc shape, and is composed of one guide groove that regulates while moving the virtual rotation center. Hinge structure. The hinge structure of the refrigerator according to claim 1 or 2, wherein the lower guide member is integrally formed with a latch portion for a stopper that can be engaged with the lower hinge member. Any of claims 1 to 3, wherein the stopper has a stopper that abuts on the lower hinge member and restricts the opening of the door, and the stopper is attached to the lower part of the door together with the lower guide member. The hinge structure of the refrigerator described in the first item. The hinge structure of a refrigerator according to any one of claims 1 to 4, wherein a cover wall covering the hinge member and the front surface side of the guide member is formed on the door. The hinge structure for a refrigerator according to claim 5, wherein the hinge member is formed with a notch for receiving an end portion of the cover wall when the door is opened.

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