KR102476694B1 - Refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator.
The refrigerator of the present invention includes a cabinet having a storage compartment; a first door and a second door opening and closing the storage compartment; a filler rotatably connected to the first door and preventing leakage of cold air from the storage compartment between the first door and the second door; and a hinge assembly rotatably connecting the pillar to the first door, wherein the hinge assembly includes: a hinge body fixed to the first door and having a shaft; and a damping mechanism installed on the pillar and reducing the rotational speed of the pillar while the pillar rotates around the shaft.

Description

Refrigerator {Refrigerator}

The present invention relates to a refrigerator.

In general, a refrigerator is a device for storing food at a low temperature. The refrigerator may include a refrigerating compartment and a freezing compartment provided below the refrigerating compartment. The refrigerator also includes a plurality of refrigerating compartment doors for opening and closing the refrigerating compartment and a freezing compartment door for opening and closing the freezing compartment.

The plurality of refrigerating compartment doors are arranged in left and right directions to independently open and close the refrigerating compartment. The plurality of refrigerating compartment doors may include a first refrigerating compartment door and a second refrigerating compartment door disposed on the right side of the first refrigerating compartment door.

Korean Patent Publication No. 2006-0075396, which is a prior document, discloses a refrigerator having a filler.

The refrigerator includes a left refrigerating compartment door and a right refrigerating compartment door, and the left refrigerating compartment door has a pillar for preventing cold air from flowing out between the refrigerating compartment doors when each refrigerating compartment door closes the refrigerating compartment. It is provided rotatably.

The filler unfolds while being inserted into a holder provided in the refrigerating compartment when the left refrigerating compartment door is closed, and is folded while being removed from the holder when the left refrigerating compartment door is opened. Also, when the left refrigerator door is opened, the filler returns to the original position from the sealing position by the elastic force of the spring.

However, according to the filler of the prior literature, since spring elasticity acts on the filler in the process of opening the left refrigerator compartment door, the filler collides with the left refrigerator door in the process of folding the filler, resulting in collision noise.

In this way, when the filler and the left refrigerator door collide, there is a problem in that surface damage occurs at the collision portion between the filler and the left refrigerator door due to repetitive opening of the left refrigerator door.

An object of the present invention is to provide a refrigerator in which noise caused by collision between a filler and a door is prevented during rotation of the filler when the door is opened.

An object of the present invention is to provide a refrigerator in which surface damage of the filler or door due to collision between the filler and the door is prevented by reducing the rotational speed of the filler when the door is opened.

A refrigerator of the present invention for solving the above problems includes a cabinet having a storage compartment; a first door and a second door opening and closing the storage chamber; a filler rotatably connected to the first door and preventing leakage of cold air from the storage compartment between the first door and the second door; and a hinge assembly rotatably connecting the pillar to the first door.

The hinge assembly may include a damping mechanism installed on the pillar and reducing a rotational speed of the pillar while the pillar rotates.

The pillar may be rotatably connected to the first door by, for example, a plurality of hinge assemblies, and the damping mechanism is located at least at the lowermost side of the plurality of hinge assemblies so as to increase the effect of reducing the impact of the pillar and the door. It may be provided in the hinge assembly.

For example, the hinge assembly may further include a hinge body fixed to the first door and having a shaft, and a movable member connected to the shaft and movable relative to the shaft.

The movable member may rotate together with the pillar, and the damping mechanism may be connected to the movable member.

For example, the moving member may include a moving body through which the shaft passes, and a rack gear provided in the moving body, and the damping mechanism may include a damping gear meshing with the rack gear.

As another example, the damping mechanism includes a first body fixed to the pillar, a second body fixed to the hinge mechanism, and relatively rotating with the first body, and between the first body and the second body. It may contain oil to be filled.

According to the proposed invention, the rotation speed of the pillar can be reduced by the damping mechanism while the pillar rotates with respect to the door, and noise can be prevented by collision between the pillar and the door.

In addition, by reducing the rotation speed of the pillar in the process of opening and closing the door, damage to the surface of the pillar or door due to collision between the pillar and the door can be prevented.

1 is a perspective view of a refrigerator according to an embodiment of the present invention;
2 is a partial perspective view of a refrigerator showing an open state of a first refrigerating compartment door according to the present invention;
Figure 3 is an exploded perspective view of a filler according to an embodiment of the present invention.
4 is an enlarged perspective view of part A of FIG. 3;
5 is a view showing a lower hinge assembly and a damping mechanism according to an embodiment of the present invention.
6 is a view showing a state in which a filler is folded when a first refrigerating compartment door is opened according to an embodiment of the present invention;
7 and 8 are views showing the action of the hinge assembly in the process of folding the pillar of FIG. 6;
9 is a view showing a lower hinge assembly and a damping mechanism according to another embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used to describe components of an embodiment of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. When an element is described as being “connected,” “coupled to,” or “connected” to another element, that element may be directly connected or connected to the other element, but there may be another element between the elements. It should be understood that may be "connected", "coupled" or "connected".

1 is a perspective view of a refrigerator according to an embodiment of the present invention, and FIG. 2 is a partial perspective view of a refrigerator showing a state in which a first refrigerating compartment door is opened according to the present invention.

1 and 2, a refrigerator 1 according to an embodiment of the present invention includes a cabinet 10 in which a refrigerating compartment 11 and a freezing compartment 12 are formed, and a hinge assembly in the cabinet 10. It may include a plurality of refrigerating compartment doors rotatably connected by the refrigerating compartment 11 and a freezing compartment door 23 for opening and closing the freezing compartment 12 .

The plurality of refrigerating compartment doors may include a first refrigerating compartment door 20 and a second refrigerating compartment door (not shown) arranged in a left-right direction.

The first refrigerating compartment door 20 may be rotatably connected to the left side of the cabinet 10, and the second refrigerating compartment door (not shown) may be rotatably connected to the right side of the cabinet 10. .

In some cases, the plurality of refrigerating compartment doors may have one or more additional doors in addition to the two doors.

The freezing chamber door 23 may open and close the freezing chamber 13 by sliding, for example. That is, the freezer compartment door may be, for example, a drawer-type door.

A pillar 30 may be provided on one of the first refrigerating compartment door 20 and the second refrigerating compartment door. The filler 30 serves to block cold air from the refrigerating compartment 11 from leaking through gaps between the plurality of refrigerating compartment doors when the refrigerating compartment 11 is closed by the plurality of refrigerating compartment doors.

FIG. 1 shows that the filler 30 is provided on the first refrigerating compartment door 20 as an example.

The first refrigerator compartment door 20 may include an outer case 21 and a door liner 22 connected to the outer case 21 . For example, the pillar 30 may be rotatably connected to the door liner 22 .

A holder 13 in which an upper end of the filler 30 can be accommodated may be provided in the refrigerating compartment 11 . For example, the holder 13 may be disposed on an upper wall of the refrigerating compartment 11 . As another example, it is also possible that the holder 13 is disposed on the lower wall of the refrigerating compartment 11 and the lower end of the filler 30 is accommodated in the holder 13 .

The holder 13 may include a guide part 132 for accommodating the upper end of the filler 30 and guiding rotation of the filler 30 when the first refrigerator door 20 is closed. .

The guide part 132 is formed in a groove shape and round, and the pillar 30 can be rotated as the end of the pillar 30 moves along the guide part 132 .

That is, when the first refrigerating compartment door 20 is closed, the filler 30 may be unfolded by interaction with the holder 13 . Accordingly, the filler 30 blocks communication between the plurality of refrigerating compartment doors and the refrigerating compartment 11 .

On the other hand, when the first refrigerating compartment door 20 is opened, the filler 30 is folded by interaction with the holder 13 . In this embodiment, the folded state of the filler 30 is a state in which the filler 30 is in contact with the side surface of the first refrigerating compartment door 20 (for example, the door liner).

In the present specification, the state of the pillar 30 as shown in FIG. 1 may be referred to as a state in which the pillar 30 is unfolded, and the state of the pillar 30 as shown in FIG. 2 may be referred to as a state in which the pillar 30 is folded. can do.

Hereinafter, the structure of the filler 30 of the present embodiment will be described in detail.

3 is an exploded perspective view of a pillar according to an embodiment of the present invention, FIG. 4 is an enlarged perspective view of part A of FIG. 3, and FIG. 5 is a view showing a lower hinge assembly and a damping mechanism according to an embodiment of the present invention. to be.

3 to 5, the pillar 30 of the present embodiment includes a first pillar body 310 and coupled to the first pillar body 310. A second filler body 320 may be included.

The filler 30 may further include an insulator 322 accommodated between the first filler body 310 and the second filler body 320 .

The insulator 322 may be separately manufactured and inserted between the first pillar body 310 and the second pillar body 320 . Alternatively, by injecting a foamed liquid in a state in which the first filler body 310 and the second filler body 320 are coupled and then cooling, the heat insulator 322 is formed between the first filler body 310 and the second filler body 320. It may be formed between the filler bodies 320.

The filler 30 may further include a heater 330 to prevent frost from forming on the filler 30 . For example, the heater 330 may be disposed to contact the second filler body 320 as a planar heater.

The filler 30 may further include a cover 340 covering the heater 330 . For example, the cover 340 may be coupled to the second pillar body 320 to cover the heater 330 .

When the filler 30 is folded, the first filler body 310 contacts the side surface of the first refrigerator door 20, and when the filler 30 is unfolded, the cover 340 faces the outside. You see.

In addition, the insulator 320 blocks heat generated by the heater 330 from being transferred to the refrigerating compartment 11 .

In addition, the filler 30 may be rotatably connected to the first refrigerating compartment door 20 by a plurality of hinge assemblies 350 , 360 , and 370 .

The plurality of hinge assemblies 350 , 360 , and 370 may be spaced apart from each other in a vertical direction so that the filler 30 smoothly rotates with respect to the first refrigerating compartment door 20 .

In addition, at least the lowermost hinge assembly 370 among the plurality of hinge assemblies 350, 360, and 370 is a damping mechanism 390 for reducing the rotational speed of the pillar 30 in the process of folding the pillar 30 can include

For example, the plurality of hinge assemblies 350, 360, and 370 include an upper hinge assembly 350 provided on the upper side of the pillar 30 and an intermediate hinge assembly provided on the middle part of the pillar 30 ( 360) and a lower hinge assembly 370 provided on the lower side of the pillar 30.

In this embodiment, as an example, the pillar 30 includes three hinge assemblies, but in this embodiment, the number of hinge assemblies is not limited. However, for smooth rotation of the pillar 30, it is preferable that a plurality of hinge assemblies are provided. For example, it is also possible that the intermediate hinge assembly is omitted, and hinge assemblies are respectively provided on the upper and lower sides of the pillar 30 .

A protrusion 352 for interacting with the holder 13 may be provided on an upper side of the pillar 30 . The protruding portion 352 protrudes upward from the filler 30 and is accommodated in the guide portion 132 of the holder 13 when the first refrigerating compartment door 20 is closed so that the filler 30 rotates. . The protrusion 352 may be elastically supported by an elastic member 354 .

Hereinafter, the lower hinge assembly 370 will be described in detail.

The lower hinge assembly 370 includes a hinge body 371, a movable member 380 movably connected to the hinge body 371, and a damping mechanism connected to the movable member 380. (390) may be further included.

The hinge body 371 may be fixed to the first refrigerating compartment door 20 to provide a rotational center of the filler 30 .

The hinge body 371 includes, for example, a fixing part 372 fixed to the door liner 22 of the first refrigerator compartment door 20, a cam part 373 extending from the fixing part 372, and the A shaft 375 extending from the cam portion 373 may be included.

A concave-convex portion 374 may be provided on the upper side of the cam portion 373 . The concave-convex portions 374 may include obstetrical and gynecological bone portions that are alternately disposed.

In a state in which the fixing part 372 is fixed to the door liner 22 , the cam part 373 may be located inside the pillar 30 .

When the pillar 30 rotates while the cam part 373 is located inside the pillar 30, the first pillar body 310 prevents interference between the pillar 30 and the cam part 373. ) may be provided with a slot 311 for interference prevention.

The shaft 375 may be integrally formed with the cam part 373 or may be fixed to the cam part 373 . The shaft 375 may extend upward from the cam part 373 . In addition, a portion of the shaft 375 may also extend downward from the cam part 374 for stable rotation of the pillar 30 .

The diameter of the shaft 375 may be smaller than that of the cam part 373 , and the moving member 380 may be coupled to the shaft 375 .

A rotation guide 314 accommodating the shaft 375 may be provided in the first pillar body 310 . When the shaft 375 is accommodated in the rotation guide 314 and the pillar 30 is rotated, the pillar 30 can be stably rotated around the shaft 375 .

The shaft 375 may pass through the moving member 380 . To this end, the moving member 380 may include a moving body 382 having a shaft hole 383 through which the shaft 375 passes.

The movable body 382 may be formed in a cylindrical shape, for example. A concave-convex part 384 having a shape corresponding to the concave-convex part 374 of the cam part 373 may be provided on the lower side of the movable body 382 .

The uneven part 384 of the movable body 382 may engage with the uneven part 374 of the cam part 373 .

In a state in which the movable body 382 is connected to the shaft 375 , the movable member 380 may move up and down along the shaft 375 during rotation of the pillar 30 .

At this time, a rotation prevention protrusion 385 is provided on the movable body 382 to prevent the movable body 382 from rotating relative to the first pillar body 310 during the rotation process of the first pillar body 310 . may be provided.

The anti-rotation protrusions 385 may be spaced apart from each other in a circumferential direction of the moving body 382, although not limited thereto.

The first pillar body 310 includes a protrusion guide 315 in which the anti-rotation protrusion 385 is accommodated so that the movable body 382 can move up and down while allowing rotation with the movable body 382. may be provided.

The protrusion guide 315 may extend in a vertical direction. Accordingly, the anti-rotation protrusion 385 may move up and down within the protrusion guide 315 when the moving body 382 moves up and down while being accommodated in the protrusion guide 315 .

The moving member 380 may further include a connection part 387 to be connected to the damping mechanism 390 .

The connection part 387 may include, for example, a rack gear extending in a vertical direction from an outer circumferential surface of the moving body 382 .

The damping mechanism 390 includes a housing 392 filled with viscous fluid, a one-way bearing (not shown) disposed on one side of the housing 392, and rotatably inside the housing 394. It may include a rotating body (not shown) disposed and connected to the one-way bearing, and a damping gear 396 connected to the one-way bearing.

The one-way bearing may include, for example, an outer wheel, an inner wheel, and a ball installed between the outer wheel and the inner wheel and rolling. Also, the rotating body is connected to the outer wheel, and the damping gear 396 is connected to the inner wheel.

The damping gear 396 may be connected to the rack gear. Accordingly, the damping gear 396 is rotatable in forward and reverse directions by the vertical movement of the movable member 380 .

For example, when the damping gear 396 is rotated in a first direction (for example, a forward direction), the rotational force of the inner wheel is not transmitted to the outer wheel while the ball rolls, so that the damping gear 396 is idle. will rotate with

On the other hand, when the damping gear 396p is rotated in the second direction (for example, the reverse direction), the ball disposed between the inner wheel and the outer wheel is constrained so that the inner wheel and the outer wheel rotate together. When the outer wheel is rotated, a damping force is generated as the rotating body connected to the outer wheel is rotated in contact with the viscous fluid.

The housing 392 may be fixed to one or more of the first pillar body 310 and the second pillar body 320 .

For example, FIG. 5 illustrates that the housing 392 is fixed to the second pillar body 320 .

The housing 392 is provided with a first fastening part 394 having a first fastening hole 393, and a second fastening for fastening the first fastening part 394 to the second pillar body 320. A portion 322 may be provided. A second fastening hole 324 may be formed in the second fastening part 322 .

For example, a pair of second fastening parts 322 may be spaced apart from each other, and a pair of first fastening parts 394 may be fitted to each of the pair of second fastening parts.

Further, in a state in which the first fastening parts 394 and the second fastening parts 322 are in contact with each other, the fastening member may be fastened to the first fastening hole 393 and the second fastening hole 324 .

The lower hinge assembly 370 may further include an elastic member 400 elastically supporting the movable member 380 .

The elastic member 400 is the movable member ( 380) to provide elasticity.

For example, the elastic member 400 may be a coil spring, and may be seated on an upper side of the movable member 380 to press the movable member 380 downward.

Accordingly, a state in which the concave-convex portion 384 of the movable body 382 and the concave-convex portion 374 of the cam portion 373 are engaged can be maintained by the elastic member 400 .

When the concave-convex portion 384 of the movable body 382 and the concave-convex portion 374 of the cam portion 373 are maintained in engagement, rotation of the pillar 30 may be restricted. That is, unless a force greater than the elastic force of the elastic member 400 is applied, the pillar 30 may maintain a rotated state (folded state or unfolded state).

The elastic member 400 may surround the shaft 385 penetrating the moving member 380 while being seated on the moving member 380 .

Hereinafter, an operation of the filler 30 when the first refrigerating compartment door is opened and closed will be described.

6 is a view showing how the pillar is folded when the first refrigerating compartment door is opened according to an embodiment of the present invention, and FIGS. 7 and 8 are views showing the action of the hinge assembly in the process of folding the pillar of FIG. 6 to be. 7 shows a state in which the filler is rotated by a first angle in the folding direction, and FIG. 8 shows a state in which the filler is rotated in the folding direction by a second angle greater than the first angle.

1 to 7, when the first refrigerating compartment door 20 is closed, the protruding portion 352 of the filler 30 is accommodated in the accommodating portion 132 of the holder 13, and the The filler 30 is in an unfolded state.

And, since the elastic member 400 presses the movable member 380 downward in a state in which the pillar 30 is unfolded, the concave-convex portion 384 of the movable body 382 is formed on the cam portion 373. It exists in a state coupled with the concave-convex portion 374.

In this state, when the first refrigerating compartment door 20 is rotated clockwise with reference to FIG. 6 to open the first refrigerating compartment door 20, the protruding portion 352 guides the holder 13 to the guide portion ( 132), the pillar 30 rotates counterclockwise.

When the pillar 30 rotates counterclockwise, the concave-convex part 384 of the movable body 382 slides along the concave-convex part 374 of the cam part 373, and the movable body ( 382 is rotated to release the coupling between the concave-convex portion 384 of the moving body 382 and the concave-convex portion 374 of the cam portion 373.

For example, when the pillar 30 is rotated by a first angle during the rotation process of the pillar 30, the peak portion of the concave-convex portion 384 of the moving body 382 is the concave-convex portion of the cam portion 373 ( 374 is slid along the peak, and is located at the highest point of the peak of the concavo-convex portion 374 of the cam portion 373. And, the elastic member 400 is contracted so that elastic force is accumulated.

In this process, the movable body 382 rotates together with the filler bodies 310 and 320 and rises with respect to the filler bodies 310 and 320 . When the movable body 382 ascends, the damping gear 396 meshed with the rack gear of the movable body 382 is rotated in a first direction (counterclockwise with reference to FIG. 7 ).

As described above, the damping gear 396 is in an idle state while being rotated in the first direction, so that damping force does not act on the damping gear 396 .

In the state shown in FIG. 7 , when the pillar 30 is rotated at an angle greater than the first angle, as shown in FIG. 374) climbs over the hillside and is located in the valley.

Then, the movable body 382 rotates together with the filler bodies 310 and 320, and moves downward with respect to the filler bodies 310 and 320 by the elastic force and its own weight of the elastic member 400.

When the movable body 382 moves downward, the damping gear 396 meshed with the rack gear of the movable body 382 is rotated in the second direction (clockwise direction with reference to FIG. 8 ).

As described above, when the damping gear 396 is rotated in the second direction, a damping force is generated as the rotating body provided inside the housing 392 contacts the viscous fluid and rotates. Since the damping force acts as a rotational resistance of the damping gear 396, the rotational speed of the damping gear 396 in the second direction is reduced compared to the rotational speed in the first direction by the damping force.

Therefore, when the pillar 30 is rotated more than the first angle, the rotational speed of the pillar 30 can be reduced by the damping mechanism 390, so that the pillar 30 in the process of folding the pillar 30 ) and the first refrigerating compartment door 20 may minimize noise.

In addition, when the first refrigerating compartment door 20 is opened, the rotational speed of the filler 30 is reduced, so that the filler 30 or the first refrigerating compartment door 20 may collide with the filler 30. Surface damage of the door 20 may be prevented.

In this embodiment, when the damping mechanism 390 is located at the lowermost hinge assembly 370 among the plurality of hinge assemblies 350, 360, and 370, collision noise generated during the folding of the pillar 30 (or impulse) can be maximized.

Specifically, while the protruding part 352 of the pillar 30 is removed from the guide part 132 of the holder 13, a rotational force for rotating the pillar 30 is generated.

This rotational force acts first on the side of the protrusion 352 while acting last on the lowermost hinge assembly 370 of the pillar 30 .

Therefore, when the protruding part 352 of the pillar 30 is removed from the guide part 132 of the holder 13, looking at the amount of rotation of the pillar 30 in the vertical direction, The amount of rotation of the upper part is greater than that of the lower part.

This is because after the protrusion 352 of the pillar 30 is removed from the guide part 132 of the holder 13, the lower part of the pillar 30 must be rotated more than the remaining angle at which the upper part of the pillar 30 must be rotated. means that the residual angle to do is large.

As the remaining angle to be rotated at the pillar 30 increases, the amount of impact between the pillar 30 and the first refrigerating compartment door 20 increases when the pillar 30 is folded.

Therefore, in the present embodiment, when the damping mechanism 390 is provided in at least the lowermost hinge assembly 370 of the plurality of hinge assemblies, the impact reduction width of the pillar 30 and the first refrigerator compartment door 20 is maximized and thus maximize the noise reduction effect.

9 is a view showing a lower hinge assembly and a damping mechanism according to another embodiment of the present invention.

This embodiment is the same as the previous embodiment in other parts, but there is a difference in the type and location of the damping mechanism. Therefore, only the characteristic parts of this embodiment will be described below.

Referring to FIG. 9 , the lower hinge assembly 470 according to the present embodiment includes a hinge body 471, a movable member 480 connected to the hinge body 471 to be relatively movable, and the hinge body ( 471) and a damping mechanism 490 connected to it, and some or all of the elastic member 500 for elastically supporting the movable member 480.

The hinge body 471 may be fixed to the first refrigerating compartment door 20 to provide a rotational center of the filler 30 .

The hinge body 471 includes, for example, a fixing part 472 fixed to the door liner 22 of the first refrigerator compartment door 20, a cam part 473 extending from the fixing part 472, and the An upper shaft 475 may be included in the cam portion 473 .

A concave-convex portion 474 may be provided on the upper side of the cam portion 473 . The concave-convex portions 474 may include obstetrical and gynecological bone portions that are alternately disposed.

The upper shaft 475 may be integrally formed with the cam part 473 or may be fixed to the cam part 473 .

The upper shaft 475 may have a smaller diameter than the cam part 473 , and the moving member 480 may be coupled to the shaft 475 .

The moving member 480 may include a moving body 482 coupled to the upper shaft 475 .

Since the shape of the movable member 480 is the same as the movable member 380 of the previous embodiment except for the connecting portion, a detailed description thereof will be omitted.

The hinge body 471 may further include a lower shaft 476 (or referred to as a connection part) connected to the damping mechanism 490 .

The damping mechanism 490 may be, for example, an oil damper that performs a damping action using oil.

For example, the damping mechanism 490 includes an outer body 492 (or a first body), an inner body 493 (or a second body) rotatably installed in the outer body 492, It may include oil (not shown) filled in the outer body 492 to apply rotational resistance when the inner body 493 and the outer body 492 rotate relative to each other.

The outer body 492 may be fixed to the first pillar body 310 and the second pillar body (see 320 in FIG. 3 ).

A fixing protrusion 493 is provided on the outer body 492, and a protrusion accommodating portion (not shown) in which the fixing protrusion 493 is accommodated in the first and second pillar bodies 310 and 320. ) may be provided.

In a state where the outer body 492 is fixed to the filler bodies 310 and 320 , the outer body 492 may rotate together with the filler bodies 310 and 320 .

The inner body 493 protrudes outward from the outer body 492 and may include a coupling part 494 connected to the lower shaft 476 .

For example, the coupling part 494 may be fitted to the lower shaft 476 . The horizontal cross section of the coupling part 494 is non-circular so that the outer body 492 rotates relative to the inner body 493 while the outer body 492 rotates together with the pillar bodies 310 and 320. can be formed as

Therefore, when the coupling part 494 is coupled to the lower shaft 476, the relative rotation of the lower shaft 476 and the coupling part 494 is prevented.

According to the present embodiment, when the filler 30 is rotated in the folding direction during the opening process of the first refrigerating compartment door 20, the outer body 492 is rotated together with the filler 30, while the inner body 493 remains fixed to the hinge body 471. Accordingly, the outer body 492 is relatively rotated with respect to the inner body 493, and in this process, a damping force is generated due to rotational resistance by the oil.

In this embodiment, the damping mechanism 490 may generate a damping force not only when the pillar 30 is folded, but also when the pillar 30 is closed.

Even according to the present embodiment, there is an advantage in that noise can be minimized due to collision between the filler 30 and the first refrigerating compartment door 20 by the damping mechanism 490 .

1: refrigerator 10: cabinet
20: first refrigerator compartment door 30: filler
310: first filler body 320: second filler body
371: hinge body 380: moving member
390: damping mechanism 400: elastic member

Claims (9)

a cabinet with a storage compartment;
a first door and a second door opening and closing the storage chamber;
a filler rotatably connected to the first door and preventing leakage of cold air from the storage compartment between the first door and the second door; and
A hinge assembly rotatably connecting the pillar to the first door;
The hinge assembly,
a hinge body fixed to the first door and having a shaft;
a damping mechanism installed on the pillar and reducing the rotational speed of the pillar while the pillar rotates around the shaft; and
A moving member connected to the shaft and relatively movable with respect to the shaft; includes,
The moving member includes a rack gear,
The damping mechanism includes a damping gear meshing with the rack gear.
According to claim 1,
The pillar is rotatably connected to the first door by a plurality of hinge assemblies arranged in a vertical direction,
The damping mechanism is disposed on at least a lowermost hinge assembly among the plurality of hinge assemblies. According to claim 1,
The moving member rotates together with the filler,
The damping mechanism is connected to the moving member. According to claim 3,
The moving member includes a moving body through which the shaft passes,
The rack gear is provided in the movable body of the refrigerator. According to claim 4,
The movable body is provided with a rotation prevention protrusion for preventing relative rotation of the filler and the movable body. According to claim 1,
The damping mechanism includes a first body fixed to the pillar;
A second body fixed to the hinge body and rotating relative to the first body;
A refrigerator including oil filled between the first body and the second body. According to claim 6,
The second body includes a coupling part coupled to the shaft. According to claim 7,
The horizontal cross section of the coupling part is formed in a non-circular refrigerator. According to claim 6,
Refrigerator further comprising an elastic member for elastically supporting the moving member.

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