KR20190105369A - Damping hinge module for refrigerator door - Google Patents

Abstract

The present invention relates to a damping hinge module for a refrigerator door and, more specifically, to a damping hinge module for a refrigerator door which is mounted on a refrigerator door to slowly open and close the refrigerator door. The damping hinge module for a refrigerator door comprises: a housing mounted on a refrigerator door and provided with a first and a second inner chamber formed therein and oil accommodated in the second inner chamber; a shaft penetrating the first and the second inner chamber, wherein on end thereof is arranged in the first inner chamber and the other end thereof is arranged in the second inner chamber; a driving unit inserted and arranged in the first inner chamber and mounted on one end of the shaft; and a damping unit inserted and arranged in the second inner chamber. The driving unit semi-automatically rotates the remaining section of the housing when a portion of the housing is rotated by an external force. The other end of the shaft and an inner wall of the second inner chamber are separated to fill the oil. A difference in damping force damping rotational torque of the housing in a rotating direction of the housing is created by the damping unit arranged in the second inner chamber when the housing rotates.

Description

Damping hinge module for refrigerator door {DAMPING HINGE MODULE FOR REFRIGERATOR DOOR}

The present invention relates to a damping hinge module for a refrigerator door, and more particularly, to a damping hinge module for a refrigerator door that can be mounted on the refrigerator door to allow the refrigerator door to open and close slowly.

In general, the refrigerator comprises a main body for storing food and a door for opening and closing the food.

When the door of the refrigerator is opened by a large force by an external force, it may be damaged by colliding with another object.

In addition, when closing the refrigerator door by external force with a large force, it may cause a problem by giving a shock to the refrigerator body to give a shock to the bowl stored inside.

In order to solve this problem, conventionally, a damping force is generated when the refrigerator door is opened or closed, so that the door opens slowly and closes slowly.

However, in the conventional refrigerator door, the same damping force is applied when it is opened and closed, and when the damping force is large, the refrigerator door is opened too slowly when the damping force is large. There was a problem that the shock is applied to the refrigerator body by closing at the same speed.

Patent Publication No. 10-2006-0119459 Patent Publication No. 10-2006-0099355

The present invention is to solve the above-mentioned problems, the refrigerator door is rotated at different speeds when opened and closed, so that when the refrigerator door is opened faster than when closed, when the refrigerator door is closed than when It is an object of the present invention to provide a damping hinge module for a refrigerator door that can be closed slowly, thereby minimizing the impact on the refrigerator body when the refrigerator door is closed.

In order to achieve the above object, the damping hinge module for a refrigerator door of the present invention includes: a housing mounted to the refrigerator door, and having a first interior chamber and a second interior chamber formed therein, wherein the second interior chamber contains oil; A shaft which penetrates the first and second chambers, one end of which is disposed in the first chamber and the other end of which is disposed in the second chamber; A drive unit inserted into the first chamber and mounted to one end of the shaft; And a damping part inserted into and disposed in the second chamber, wherein the driving unit rotates the remaining section of the housing semi-automatically during a partial rotation of the housing by an external force, and the other end of the shaft and the second chamber of the second chamber. The inner walls are spaced apart from each other to fill the oil, and a difference occurs in the damping force that buffers the rotational torque of the housing according to the rotational direction of the housing by the damping part disposed in the second inner chamber during rotation of the housing. Characterized in that.

The damping unit is mounted to the inner circumferential surface of the housing in the second inner chamber to rotate with the housing, the pressing member in contact with the outer circumferential surface of the shaft; A blade mounted on an outer circumferential surface of the shaft in the second inner chamber and adjusting a gap with an inner wall of the second inner chamber, wherein the pressing member is filled with oil in the second inner chamber when the housing is rotated. Rotational movement while pressing the blade, the blade adjusts the gap with the inner wall of the second inner chamber according to the rotational direction of the pressing member by the housing, the oil filled in the second inner chamber is caused by the rotation of the housing The rotational torque of the housing is buffered while the pressure member moves through the gap between the blade and the inner wall of the second chamber.

The blade is formed in the shape of a rod rotatably mounted on the outer circumferential surface of the shaft while being disposed in the same direction as the longitudinal direction of the shaft, the blade is rotated relative to the shaft by the oil moving by the pressing member The gap with the inner wall of the second inner chamber is adjusted according to the rotation direction of the housing.

The blade has a wing tip protruding in the direction of the inner wall of the housing, the wing tip is disposed deviating in one direction from an imaginary line connecting the center of the shaft and the center of the blade, the center of the blade and the wing tip The distance therebetween is longer than the distance between the center of the blade and the inner wall of the second boudoir and the blade tip is spaced apart from the inner wall of the second boudoir while the blade is rotated by the oil moving by the pressing member. The gap with the inner wall of the said 2nd interior chamber is adjusted.

Alternatively, the blade is formed in a rod shape is mounted on the shaft in the same direction as the longitudinal direction of the shaft, the blade has a wing tip protruding in the direction of the inner wall of the housing, the wing tip and the center of the shaft It is disposed in one direction from an imaginary line connecting the center of the blade, the distance between the center of the blade and the wing tip is longer than the distance between the center of the blade and the inner wall of the second inner chamber, by the pressing member The wing tip is elastically deformed by the moving oil to be spaced apart or in contact with the inner wall of the second inner chamber, thereby controlling the gap between the inner wall of the second inner chamber.

The gap between the blade and the inner wall of the second interior compartment when the refrigerator door is changed from the open state to the closed state is the gap between the blade and the inner wall of the second interior compartment when the refrigerator door is converted to the open state from the closed state Smaller, the rotational torque of the housing mounted on the refrigerator door and rotating together when the refrigerator door is switched from an open state to a closed state is further cushioned.

The pressing member is formed in the pressing groove is concave in both directions to rotate.

A support jaw is formed in the housing between the first chamber and the second chamber, and the driving unit includes: a sliding cam disposed to be linearly movable in the first chamber; A turning cam rotatably inserted into the first chamber and having one end engaged with one end of the sliding cam and fixedly coupled to one end of the shaft; A spring disposed between the other end of the sliding cam and the support jaw; wherein the sliding cam is rotated while compressing the spring to a bending point of the turning cam when the housing is rotated, and then the turning cam is curved. After passing the point, the spring is rotated semi-automatically with the housing by the elastic restoring force.

According to the damping hinge module for a refrigerator door of the present invention as described above has the following advantages.

According to the present invention, a difference occurs in the damping force for buffering the rotational torque of the housing, so that the refrigerator door rotates at different speeds when the refrigerator door is opened and closed.

In particular, by the hinge module of the present invention by closing the refrigerator door when the refrigerator door is closed to rotate more slowly than when opened, it is possible to minimize the amount of impact and impact sound applied to the refrigerator body while the refrigerator door is closed.

1 is a configuration diagram showing a state in which a damping hinge module for a refrigerator door mounted on a refrigerator according to an embodiment of the present invention;
2 is a perspective view of a damping hinge module for a refrigerator door according to an embodiment of the present invention;
3 is an exploded perspective view of a damping hinge module for a refrigerator door according to an embodiment of the present invention;
4 is a cross-sectional view taken along line AA and BB of FIG.
FIG. 5 is a cross-sectional structure diagram when the housing partially rotates and the sliding cam and the turning cam reach the bending point in FIG. 4;
6 is a cross-sectional structural view of a state in which the housing is further rotated in FIG. 5;
Figure 7 is a cross-sectional view for explaining the operation of the damping unit in the damping hinge module for a refrigerator door in accordance with an embodiment of the present invention.

The damping hinge module for a refrigerator door of the present invention is mounted on the refrigerator door 62 as shown in FIG. 1, so that the refrigerator main body 61 can be opened and closed while the refrigerator door 62 is rotated.

2 to 4, the present invention includes a housing 10, a shaft 20, a driving unit 30, and a damping unit 40.

The housing 10 has a hollow cylindrical shape, and a first inner chamber 11 and a second inner chamber 12 are formed therein.

The first interior chamber 11 and the second interior chamber 12 are in communication with each other while the shaft 20 is not inserted into the housing 10.

The second chamber 12 contains oil 14 for damping.

In addition, a support jaw 13 having a smaller diameter than the first inner chamber 11 and the second inner chamber 12 is formed between the first inner chamber 11 and the second inner chamber 12 inside the housing 10. It is.

The housing 10 is mounted to the refrigerator door 62 in a vertical direction as shown in FIG. 1, and rotates together when the refrigerator door 62 is rotated.

The shaft 20 penetrates through the first interior chamber 11 and the second interior chamber 12, one end of which is disposed in the first interior chamber 11, and the other end of the shaft 20 is disposed in the second interior chamber 12.

The driving unit 30 is inserted into the first inner chamber 11 and mounted to one end of the shaft 20.

When the hinge module of the present invention is mounted on the refrigerator door 62, the driving unit 30 is disposed at the top and coupled to the bracket 63 protruding from the refrigerator main body 61.

Thus, the housing 10 and the refrigerator door 62 rotate about the driving unit 30 and the shaft 20.

The driving unit 30 rotates the remaining section of the housing 10 automatically when the housing 10 is partially rotated by an external force.

If the drive unit 30 can rotate the remaining section of the housing 10 semi-automatically during the partial rotation of the housing 10, it may be made of various structures in addition to the structure shown in this embodiment.

In the present embodiment, the drive unit 30 includes a sliding cam 31, a turning cam 32, and a spring 33.

The sliding cam 31 is inserted into the first interior chamber 11 so as to be linearly movable.

To this end, guide protrusions protrude from both sides of the sliding cam 31, and guide grooves to which the guide protrusion is inserted and move are formed on the inner wall of the first inner chamber 11.

The shaft 20 is disposed through the sliding cam 31, and the shaft 20 and the sliding cam 31 rotate independently of each other.

That is, when one of the shaft 20 or the sliding cam 31 is rotated, the other one does not rotate dependently.

A curved portion is formed at one end of the sliding cam 31.

The turning cam 32 is rotatably inserted into the first inner chamber 11.

The turning cam 32 has a curved portion formed at one end thereof and engages with one end of the sliding cam 31.

The turning cam 32 is fixedly coupled to one end of the shaft 20 to rotate together with the shaft 20.

The turning cam 32 is coupled to the bracket 63, so that the shaft 20 is fixedly coupled to the sagging bracket 63 through the turning cam 32.

The spring 33 is disposed between the other end of the sliding cam 31 and the support jaw 13 to elastically press the sliding cam 31 toward the turning cam 32.

Due to this structure, the sliding cam 31 rotates together with the housing 10 when the housing 10 is mounted on the refrigerator door 62 as shown in FIGS. 4 to 5. The spring 33 is moved in a direction compressing the spring 33, and the sliding cam 31 is rotated while compressing the spring 33 to the bending point of the turning cam 32 and then the turning cam. After the bending point of (32), the sliding cam 31 is rotated semi-automatically with the housing 10 while moving in the direction of the turning cam 32 by the elastic restoring force of the spring (33).

That is, the housing 10 rotates semi-automatically, and the sliding cam 31 rotates together with the housing 10 while linearly moving.

In addition, the turning cam 32 and the shaft 20 are not rotated and are maintained as they are.

The damping portion 40 is inserted into the second interior chamber 12.

The other end of the shaft 20 and the inner wall of the second inner chamber 12 are spaced apart from each other so that the oil 14 is filled in the space.

The oil 14 and the damping part 40 generate a damping force when the housing 10 rotates, thereby reducing the rotational torque of the housing 10.

In particular, the damping part 40 is disposed in the second chamber 12, the damping to buffer the rotational torque of the housing 10 in accordance with the rotation direction of the housing 10 during the rotation of the housing 10 Make a difference.

That is, the damping part 40 generates different damping forces according to the rotational direction of the housing 10, so that the rotational torque generated when the housing 10 is rotated is rotated in the rotational direction of the housing 10. Therefore, it should be buffered to different sizes.

Conventional damping unit 40 is to generate the same damping force regardless of the rotation direction of the rotating body.

However, according to the present invention, the damping unit 40 generates different damping forces according to the rotational direction of the housing 10, and thus, when the housing 10 is rotated, the housing 10 rotates in accordance with the rotational direction thereof. There is a difference in that it causes a difference.

The damping part 40 includes a pressing member 41 and a blade 43.

The pressing member 41 is mounted on the inner circumferential surface of the housing 10, that is, the inner wall of the second inner chamber 12, in the second inner chamber 12, and rotates together with the housing 10.

The pressing member 41 is disposed only on a part of the second inner chamber 12 and is installed to contact the outer circumferential surface of the shaft 20.

That is, the pressing member 41 is mounted on the inner wall of the second inner chamber 12 and provided to contact the outer circumferential surface of the shaft 20.

In the pressing member 41, the pressing groove 42 is formed in a concave direction in both directions to rotate.

Therefore, when the pressing member 41 is rotated by the rotation of the housing 10, the oil 14 filled in the second inner chamber 12 is pushed into the pressing groove 42 while the pressing member ( 41).

 As the pressure groove 42 is formed as described above, when the pressure member 41 is opened by the oil 14 filled in the second chamber 12 during the rotation of the pressure member 41, the pressure is applied. The small gap between the member 41 and the shaft 20 becomes more intimate, so that the oil 14 does not leak through the gap between the pressing member 41 and the shaft 20, and the pressing member 41 does not leak. Can be pushed in the direction of rotation.

The blade 43 is mounted on the outer circumferential surface of the shaft 20 in the second inner chamber 12 to adjust the gap with the inner wall of the second inner chamber 12.

When the pressing member 41 is rotated by the rotation of the housing 10, the pressing member 41 rotates while pressing the oil 14 filled in the second inner chamber 12 and moves the blade. The damping force is generated while the oil 14 moves through the gap between the 43 and the inner wall of the second inner chamber 12.

That is, the oil 14 filled in the second inner chamber 12 is moved to the inner wall of the blade 43 and the second inner chamber 12 by the movement of the pressing member 41 by the rotation of the housing 10. The damping force is generated to cushion the rotational torque of the housing 10 while moving through the gap therebetween.

At this time, the blade 43 adjusts the gap with the inner wall of the second inner chamber 12 in accordance with the rotation direction of the pressing member 41 by the housing 10, the rotation direction of the housing 10 As a result, a difference occurs in the damping force.

The blade 43 has a rod shape and is mounted to the shaft 20 in the same direction as the longitudinal direction of the shaft 20.

The blade 43 is rotatably mounted on the outer circumferential surface of the shaft 20.

The blade 43 is rotated with respect to the shaft 20 by the oil 14 moving by the pressing member 41 of the second inner chamber 12 in the rotational direction of the housing 10. Adjust the gap with the inner wall.

To this end, the blade 43 of the present embodiment has a wing tip 44 protruding in the direction of the inner wall of the housing 10.

The wing tip 44 is disposed in one direction from an imaginary line connecting the center of the shaft 20 and the center of the blade 43.

The distance between the center of the blade 43 and the wing tip 44 is longer than the distance between the center of the blade 43 and the inner wall of the second inner chamber 12.

Therefore, the blade 43 is rotated by the oil 14 moving by the pressing member 41 while the wing tip 44 is spaced from or in contact with the inner wall of the second chamber 12. The gap with the inner wall of the inner chamber 12 is adjusted.

Unlike the present embodiment, the blade 43 may not be rotatably mounted to the shaft 20.

At this time, the wing tip 44 formed on the blade 43 is elastically deformed by the oil 14 moving by the pressing member 41 while being spaced or contacted with the inner wall of the second inner chamber 12 The gap with the inner wall of the second inner chamber 12 may be adjusted.

In order to prevent the oil 14 filled in the second chamber 12 from leaking to the outside, an o-ring is mounted on the shaft 20, and the second chamber 12 is mounted on the housing 10. ) Is fitted with a cover (15).

The hinge module of the present invention has a gap between the blade 43 and the inner wall of the second chamber 12 when the refrigerator door 62 is changed from an open state to a closed state, and the refrigerator door 62 is closed. It is preferable to make it smaller than the gap between the blade 43 and the inner wall of the second inner chamber 12 when it is converted from the open state to the open state.

As a result, the rotational torque of the housing 10 which is mounted on the refrigerator door 62 and rotates together when the refrigerator door 62 is also converted from the open state to the closed state is further buffered, thereby making the refrigerator door 62 When the door is closed more slowly than when the door is opened, the refrigerator door 61 may be shocked or minimized when the refrigerator door 62 is closed.

Hereinafter, an operation process of the present invention having the above-described configuration will be described.

The housing 10 is mounted to the refrigerator door 62, and the turning cam 32 is disposed upward and mounted to a bracket 63 mounted to the refrigerator main body 61.

In the state in which the refrigerator door 62 is closed, as shown in FIG. 4, the pressing member 41 is disposed adjacent to a position where the wing tip 44 of the blade 43 is formed, and the wing tip 44 and the inner wall of the second chamber 12 are spaced apart from each other.

In this state, when the refrigerator door 62 is opened by an external force, as shown in FIG. 5, the housing 10 is rotated, and when the housing 10 is rotated, the sliding cam 31 is rotated by the housing. While rotating together with (10), the spring 33 is moved in the compression direction by the engagement structure with the turning cam 32.

Then, when the sliding cam 31 passes the bending point of the turning cam 32, the sliding cam 31 is turned by the elastic restoring force of the spring 33 that has been compressed. The cam 32 rotates semi-automatically while moving toward the cam 32. As a result, the housing 10 and the refrigerator door 62 are semi-automatically rotated to open the refrigerator main body 61 even when no external force is applied.

In this process, the pressing member 41 coupled to the housing 10 moves while pushing the oil 14 filled in the second chamber 12, and the oil 14 is pressurized. It is pushed by the member 41 to generate a damping force while moving through the narrow gap between the blade 43 and the inner wall of the second chamber 12.

Thus, the refrigerator door 62 is slowly opened by the damping force generated by the hinge module of the present invention.

Looking at this operation in more detail, Figure 7 (a) shows the state of the damping member 40 when the refrigerator door 62 is converted from the closed state to the open state, Figure 7 (b) is a refrigerator door ( 62 shows the state of the damping member 40 when it is converted from the open state to the closed state.

As shown in FIG. 7A, in the state where the refrigerator door 62 is closed, the pressing member 41 is adjacent to the blade 43 at a position where the wing tip 44 of the blade 43 is formed. It is arranged.

In this state, when the refrigerator door 61 is rotated and opened by an external force, as shown in FIG. 7A, the housing 10 rotates in a counterclockwise direction.

As the housing 10 rotates, the pressing member 41 mounted to the housing 10 also rotates counterclockwise, and the pressing member 41 rotates to the second inner chamber 12. The filled oil 14 is pushed in a counterclockwise direction and damped while moving through the gap between the blade 43 and the inner wall of the second chamber 12.

At this time, the wing tip 44 is slightly spaced apart from the inner wall of the second inner chamber 12.

And, as shown in Figure 7 (b), in the state in which the refrigerator door 62 is opened, the pressing member 41 is the blade in the opposite position where the wing tip 44 of the blade 43 is formed It is arranged adjacent to (43).

In this state, when the refrigerator door 62 is rotated and closed by an external force, as shown in FIG. 7B, the housing 10 rotates clockwise.

As the housing 10 rotates, the pressing member 41 mounted on the housing 10 also rotates in a clockwise direction, and the pressing member 41 rotates to fill the second inner chamber 12. The oil 14 is pushed in a clockwise direction and is damped while moving through the gap between the blade 43 and the inner wall of the second chamber 12.

At this time, the moving oil 14 pushes the wing tip 44 toward the inner wall of the second inner chamber 12.

When the wing tip 44 is pushed by the oil 14, the blade 43 is rotated, thereby causing the wing tip 44 in contact with the inner wall of the second inner chamber 12.

In this case, the gap between the blade 43 and the inner wall of the second inner chamber 12 is narrower than when the refrigerator door 62 is opened, so that the oil 14 moved by the pressing member 41 is reduced. Is moved little by little through the gap between the pressing member 41 and the wing tip 44.

Thus, the housing 10 and the refrigerator door 62 are closed while rotating more slowly when closed than when opened.

As described above, according to the present invention, a difference occurs in the damping force for buffering the rotational torque of the housing 10 according to the rotational direction of the housing 10, and at different speeds when the refrigerator door 62 is opened and closed. Can be rotated.

Particularly, by the hinge module of the present invention, the refrigerator door 62 is rotated and closed more slowly than when the refrigerator door 62 is closed, thereby minimizing the amount of impact and impact sound applied to the refrigerator main body 61 while the refrigerator door 62 is closed. Can be.

The damping hinge module for a refrigerator door of the present invention is not limited to the above-described embodiment, and may be variously modified and implemented within the range in which the technical idea of the present invention is permitted.

10 housing, 11 first interior room, 12 second interior room, 13 support jaw, 14 oil, 15 cover,
20: shaft,
30: driving part, 31: sliding cam, 32: turning cam, 33: spring,
40: damping part, 41: pressing member, 42: pressing groove, 43: blade, 44: wing tip,
61: refrigerator body, 62: refrigerator door, 63: bracket.

Claims (8)

A housing mounted to the refrigerator door, the first interior chamber and the second interior chamber being formed therein, wherein the second interior chamber has oil;
A shaft which penetrates the first and second chambers, one end of which is disposed in the first chamber and the other end of which is disposed in the second chamber;
A drive unit inserted into the first chamber and mounted to one end of the shaft;
A damping part inserted into the second inner chamber is disposed;
The driving unit rotates the remaining section of the housing semi-automatically during the partial rotation of the housing by an external force,
The other end of the shaft and the inner wall of the second inner chamber is spaced apart from each other to fill the oil,
The damping hinge module for a refrigerator door, characterized in that the damping force for buffering the rotational torque of the housing in accordance with the rotation direction of the housing by the damping portion disposed in the second inner chamber when the housing rotates. The method according to claim 1,
The damping unit,
A pressing member mounted to an inner circumferential surface of the housing in the second inner chamber and rotating together with the housing and in contact with an outer circumferential surface of the shaft;
And a blade mounted on an outer circumferential surface of the shaft in the second inner chamber and adjusting a gap with an inner wall of the second inner chamber.
When the housing is rotated, the pressing member rotates while pressing the oil filled in the second inner chamber,
The blade adjusts the gap with the inner wall of the second inner chamber according to the rotation direction of the pressing member by the housing,
The oil filled in the second chamber is buffered by the rotational torque of the housing while moving through the gap between the blade and the inner wall of the second chamber by the movement of the pressing member by the rotation of the housing. Damping hinge module for doors. The method according to claim 2,
The blade is formed in a rod shape rotatably mounted on the outer peripheral surface of the shaft while being disposed in the same direction as the longitudinal direction of the shaft,
The blade damping hinge module for a refrigerator door, characterized in that the blade is rotated with respect to the shaft by the oil moving by the pressing member to adjust the gap with the inner wall of the second chamber according to the rotation direction of the housing. The method according to claim 3,
The blade has a wing tip protruding in the direction of the inner wall of the housing,
The wing tip is disposed biased in one direction from an imaginary line connecting the center of the shaft and the center of the blade,
The distance between the center of the blade and the wing tip is longer than the distance between the center of the blade and the inner wall of the second boudoir,
Damping for the refrigerator door characterized in that the blade tip is rotated by the oil moving by the pressing member while the wing tip is spaced or contacted with the inner wall of the second inner chamber to adjust the gap with the inner wall of the second inner chamber. Hinge module. The method according to claim 2,
The blade has a rod shape is mounted to the shaft in the same direction as the longitudinal direction of the shaft,
The blade has a wing tip protruding in the direction of the inner wall of the housing,
The wing tip is disposed biased in one direction from an imaginary line connecting the center of the shaft and the center of the blade,
The distance between the center of the blade and the wing tip is longer than the distance between the center of the blade and the inner wall of the second boudoir,
Damping hinge module for a refrigerator door, characterized in that the wing tip is elastically deformed by the oil moving by the pressing member while being spaced or in contact with the inner wall of the second inner chamber to adjust the gap with the inner wall of the second inner chamber. . The method according to any one of claims 2 to 5,
When the refrigerator door is changed from an open state to a closed state, a gap between the blade and the inner wall of the second chamber is,
Smaller than the gap between the blade and the inner wall of the second interior chamber when the refrigerator door is changed from the closed state to the open state,
Damping hinge module for a refrigerator door, characterized in that the rotating torque of the housing mounted on the refrigerator door and rotates together when the refrigerator door is also converted from the open state to the closed state. The method according to claim 2,
The pressing member is a damping hinge module for a refrigerator door, characterized in that the pressing groove is formed concave in both directions to rotate. The method according to claim 1,
The support jaw is formed in the housing between the first chamber and the second chamber,
The driving unit,
A sliding cam inserted into the first inner chamber so as to be linearly movable;
A turning cam rotatably inserted into the first chamber and having one end engaged with one end of the sliding cam and fixedly coupled to one end of the shaft;
A spring is disposed between the other end of the sliding cam and the support jaw;
When the housing is rotated, the sliding cam is rotated while compressing the spring to the bending point of the turning cam, and when passing through the bending point of the turning cam is semi-automatically rotated together with the housing by the elastic restoring force of the spring. Damping hinge module for refrigerator doors.

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