KR20070025353A - Door tilting structure for refrigerator - Google Patents

Abstract

A tilting structure of a door for a refrigerator is provided to prevent a storing space door from incompletely sealing the storing space by hanging a moving regulating part of a cam on a corrosion preventing pin without contacting with a roller. A tilting structure of a door for a refrigerator comprises a receptacle(32) installed at the rear of a vertical part(30) supporting a storing box placed at the storing space and rotatably supported with a roller(36) at the upper side, interlocking members interlocked with the storing space door, a cam(40) whose one side is pin-combined with the interlocking member to receive elasticity due to the spring and other side is contacted with the outer peripheral surface of the roller to be guided and to be operated with the storing space door, and a corrosion preventing pin(38) installed at the receptacle to selectively hang a moving regulating part of the cam and restrict the tilting range of the storing space door according to the tilting of the storing space door. The corrosion preventing pin is mounted at the rear of the roller.

Description

Tilting Structure For Refrigerator

1 is a side perspective view of a refrigerator compartment door constituting a tilting structure of a door for a refrigerator according to the prior art withdrawn from the refrigerator body;

Figure 2 is a rear perspective view of the vertical part constituting the tilting structure of the door for a refrigerator according to the prior art.

Figure 3 is a rear perspective view showing a preferred embodiment of the tilting structure of the door for a refrigerator according to the present invention.

Figure 4 is a rear perspective view showing the main portion of the embodiment of the present invention.

5 is a side perspective view of an embodiment of the present invention.

Figure 6 is a side view showing a coupling relationship of the interlocking member and the receptacle constituting an embodiment of the present invention.

7 is an operational state diagram showing an operating state when the storage space door constituting the embodiment of the present invention is tilted.

* Explanation of symbols for main parts of drawings *

30: vertical portion 30 ': first guide slit

32: Receptacle 32 ': Second guide slit

34: roller pin 36: roller

38: Wear prevention pin 40: Cam

41: Moving control part 41a: Pin contact groove

42: hinge 44: storage space door

44a: door liner 46: shield member

48: linking member 49: pin

50: support member 50a: working part

52: fixing member 54: spring

56: elastic member

The present invention relates to a refrigerator door, and more particularly, to a tilting structure of a door for a refrigerator for enabling the user to tilt the door according to the user's convenience.

1 and 2 illustrate a tilting structure of a door for a refrigerator according to the prior art. As shown in these figures, the overall appearance of the refrigerator is formed by the refrigerator main body 1, and the inside of the refrigerator is divided into a refrigerator compartment and a freezer compartment, which are storage spaces, by a compartment, and a storage box moved in a drawer type in the storage space ( Not shown). Such a storage box is supported by the support frame 7 to be described below and is moved in the storage space drawer type according to the user's choice.

Guide rails 3 are provided on both side walls of the storage space, and the movable rails 5 are installed on the guide rails 3 to be movable. The movable rail 5 is fastened by a fastening means such as a screw to the horizontal portion 9 of the support frame 7 supporting the storage box.

The support frame 7 is provided with a horizontal portion 9, which is a portion to which the moving rail 5 is fastened, and a vertical portion 11 extending in a direction perpendicular to the horizontal portion 9. The vertical portion 11 is formed with a recessed portion (not shown) recessed so that the interlocking member 15 to be described below is seated, and one side wall of the recessed portion of the tilting prevention member 19 to be described below. The first through hole 11a through which the fixing portion 19b is inserted is formed. The vertical portion 11 is formed with a first guide slit 11 'for guiding the movement of the cam 21 to be described below. On the rear surface of the vertical portion 11, as shown in FIG. 2, a stopper piece 11b defining a tilting range of the cam is provided.

And, the lower end of the vertical portion 11 is hinged to a hinge portion (not shown) provided at the lower end of the interlocking member 15 fastened to the storage space door 13 to be described below, the storage space door 13 The top of) causes the bottom to tilt around the axis. The storage space 13 is formed of an outdoor 13a forming an outer surface and a door liner 13b forming an inner surface, and although not shown, an external space is formed between the outdoor 13a and the door liner 13b. The heat insulation layer which interrupts heat exchange with is formed.

Interlocking members 15 are fastened by fastening means such as screws to lower edges of both sides of the door liner 13b. The interlocking member 15 is a member interlocked with the storage space door 13, and one surface thereof is installed to face one surface of the vertical portion 11.

One end of the cam 21 to be described below is fixedly installed in the interlocking member 15, and the cam 21 is guided to a surface facing the vertical portion 11 of the interlocking member 15. The second guide slit 15 'is formed.

The fixing member 17 is fastened to the upper end of the interlocking member 15 by a fastening means such as a screw. The fixing member 17 is for reliably fixing the tilting prevention member 19 to be described below to the interlocking member 15. That is, one end of the tilting prevention member 19 penetrates one surface of the fixing member 15 and then penetrates the first through hole 11a of the vertical portion 11 to the vertical portion 11 and the door liner. Make (13b) mutually restrained.

On the other hand, since one end of the cam 21 is fixedly installed in the interlocking member 15 fastened to the storage space door 13, the cam 21 is interlocked with the storage space door 13 and tilted.

In the drawing, reference numeral 23 denotes a seating portion formed around the inner edge of the support frame 7 to seat the storage box.

However, the prior art as described above has the following problems.

That is, when the storage space door 13 is used by tilting, the user may minimize the force and moment applied to the hinge portion of the lower end by sudden tilting due to the weight of the storage space door 13. The discomfort of supporting the upper end of 13) with a predetermined force is felt. Due to this inconvenience, the prior art has a problem that the user can not trust the product.

Since one end of the cam 21 is fixed to the interlocking member 15, the cam fixed to the interlocking member 15 when the other end of the cam 21 strikes the stopper piece 11b is formed. Force and moment are applied to one end of 21). Therefore, as the cam 21 repeatedly hits the stopper piece 11b due to the repeated tilting of the storage space door 13, the cam 21 is not firmly supported inside the interlocking member 15, and the There is a problem that is easily separated.

In addition, since the stopper piece 11b is formed of a synthetic resin material, there is also a problem in that wear occurs easily due to repeated bumps of the cam 21.

Accordingly, an object of the present invention is to solve the problems as described above, and to increase the durability of the parts regulating the tilting range of the storage space door.

Another object of the present invention is to prevent abrasion of the member for guiding the movement of the cam.

According to a feature of the present invention for achieving the above object, the present invention is installed on the rear surface of the vertical portion for supporting the storage box located in the storage space, the receptacle is rotatably supported on the roller; An interlocking member coupled to both sides of the door liner forming an inner surface of the storage space door and interlocked with the storage space door; A cam which is coupled to the interlocking member while receiving an elastic force by a spring and the other side is guided to be in contact with the outer circumferential surface of the roller while operating with the storage space door; And a wear prevention pin installed in the receptacle and configured to selectively move the movement control part of the cam according to the tilting of the storage space door to regulate the tilting range of the storage space door.

The wear preventing pins are provided at the rear of the rollers so as to hit the wear preventing pins first before the movement restricting portion hits the rollers.

The tip of the movement restricting portion is formed to correspond to the outer circumferential surface shape of the wear preventing pin.

One side of the cam is pin-coupled to the interlocking member, the front portion of the pin coupling portion of the cam is fixed to a support member positioned inside the interlocking member, and the rear portion of the pin coupling portion of the cam is an outer circumferential surface of the roller. It is installed to move in contact with.

A spring is installed so as to surround the support member positioned inside the interlocking member, and the spring is selectively compressed or restored by the action of the support member according to the movement of the cam.

Such a tilting structure of the door for a refrigerator according to the present invention prevents the wear of the roller to prevent the storage space door from incompletely sealing the storage space by the wear of the roller, the impact applied to the wear preventing pin by the cam There is an advantage of preventing the breakage of the anti-wear pin by dispersing.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the tilting structure of the drawer-type door for a refrigerator according to the present invention will be described in detail.

As shown in Figures 3 to 7, the vertical portion 30 is a portion corresponding to the leg of the support frame for supporting the storage box. As shown in FIG. 3, the cross section of the vertical portion 30 has a shape in which approximately 'a' and 'b' letters are connected. As shown in FIG. 5, a first guide slit 30 ′ is formed in the vertical portion 30 to guide the movement of the cam 40 to be described below.

Corresponding surfaces of the receptacle 32 are screwed to both sides of the vertical portion 30, respectively. The receptacle 32 has a cross section of approximately 'C' shape. A second guide slot 32 'is formed at a portion of the receptacle 32 corresponding to the formation position of the first guide slit 30'. The second guide slot 32 ′ serves to guide the movement of the cam 40 to be described below.

In addition, the receptacle 32 is provided with roller pins 34 penetrating both sides of the receptacle 32. As shown in FIG. 4, the roller 36 is rotatably supported by the roller pin 34. The roller 36 is rotated about the axis of rotation in accordance with the movement of the cam 40 to be described below. Such a roller 36 serves to facilitate the movement of the cam 40. On the other hand, the roller 36 is formed of a plastic material.

The receptacle 32 is provided with a wear preventing pin 38 behind the roller 36 to penetrate both sides of the receptacle 32. The wear preventing pin 38 is a portion in which the movement restricting portion 41 of the cam 40 to be described below is selectively contacted, and serves to limit the movement range of the cam 40. In addition, the wear preventing pin 38 is made to hit the wear preventing pin 38 before the movement restricting portion 41 of the cam 40 touches the roller 36 when the cam 40 moves. It also serves to prevent wear of 36).

That is, if the structure is not provided with the wear preventing pin 38, the movement restriction portion 41 is repeatedly impacted on the roller 36 in accordance with the tilting of the storage space door 44 to be described below. In addition, since the roller 36 is formed of a plastic material, wear is easily generated on the outer circumferential surface of the roller 36. The wear of the roller 36 causes a problem that prevents the storage space door 44 from completely enclosing the storage space, as will be described later, such a problem as described above wear-resistant pin 38 according to the present invention This is solved by letting the movement restricting portion 41 hit first. On the other hand, the wear preventing pin 38 is preferably formed of a steel (steel) material to withstand the impact well.

The cam 40 moving through the first guide slit 30 ′ and the second guide slot 32 ′ moves in a curved state in close contact with the outer circumferential surface of the roller 36. The upper portion of the cam 40 is provided with a movement restricting portion 41 protruding upward. The movement restricting portion 41 serves to regulate the movement range of the cam 40 to the part which contacts the wear preventing pin 38 when the cam 40 moves. The tip of the movement restricting portion 41 is provided with a pin contact groove 41a formed to correspond to the shape of the outer circumferential surface of the wear preventing pin 38. The pin contact groove 41a is a portion that selectively contacts the wear preventing pin 38 according to the movement of the cam 40, and serves to evenly distribute the impact applied to the wear preventing pin 38.

The lower side of the receptacle 32 is installed so that one side of the hinge portion 42 is supported. The other side of the hinge portion 42 is pin-coupled to the interlocking member 48 to be described below. This hinge portion 42 allows the interlocking member 48 to rotate relative to the receptacle 32.

On the other hand, the storage space door 44 is in close contact with the vertical portion 30 selectively. A shielding member 46 for screwing the interlocking member 48 to be described below is screwed on both sides of the door liner 44a forming the inner surface of the storage space door 44. The shielding member 46 has a substantially 'c' shaped cross section, and both surfaces thereof are formed to face the corresponding surface of the vertical portion 30. The shielding member 46 shields the interlocking member 48 to prevent breakage of the interlocking member 48 and the components therein, and prevents the interlocking member 48 from being visible to the naked eye when the storage space door 44 is tilted. It serves to beautify the appearance of the storage door 44.

Inside the shielding member 46, as shown in FIG. 6, an interlocking member 48 having one side of the cam 40 to be pinned is provided. By such a pin coupling, the cam 40 can rotate while drawing a curve around the pin 49. The interlocking member 48 has a cross-section of approximately 'c' shape. The interlocking member 48 is screwed to the door liner 44a and rotates in conjunction with the storage space door 44.

Inside the interlocking member 48 is provided a support member 50 formed long in the vertical direction. The lower end of the support member 50 is coupled to the front end of the cam 40 to be bound to each other. The lower portion of the support member 50 is provided with a working portion (50a) protruding outward. The acting portion 50a serves to cause the restoring force of the spring 54 to be described below to act on the support member 50. As the restoring force of the spring 54 is applied to the acting portion 50a as described above, the front end portion of the cam 40 receives the restoring force downward by the spring 54, so that the rear end portion of the cam 40 goes downward. It can be moved in close contact with the roller 36 without sagging. On the other hand, the upper end of the support member 50 is supported to be movable in the vertical direction to the fixing member 52 is fixed to the upper portion of the interlocking member 48.

The outer side of the support member 50 is provided with a spring 54 so as to surround the support member 50. The upper end of the spring 54 is supported on one side of the interlocking member 48, and the lower end is supported on the acting portion 50a of the support member 50. Such a spring 54 is in a state of being slightly compressed by the support member 50 when the storage door 44 is not tilted.

In addition, the spring 54 is further compressed by the support member 50 when the storage space door 44 is tilted to apply a greater restoring force to the acting portion 50a. Thus, the spring 54 acts to prevent the deflection of the rear end of the cam 40 as well as to enable the soft tilting of the storage space 44 by applying a restoring force downward to the action portion 50a. .

 In the drawing, reference numeral 56 is fixedly installed on the upper end of the shielding member 46 and selectively adhered to one side of the vertical portion 30 according to the tilting of the storage space door 44 to be stored together with the spring 54. It is an elastic member that controls the tilting of the space door 44.

Hereinafter, the operation of the tilting structure of the door for a refrigerator according to the present invention having the configuration as described above will be described in detail.

Looking at the assembly process of the first embodiment, the receptacle 32 is installed on the rear surface of the vertical portion 30 by screwing. The interlocking member 48 is fixedly installed to the door liner 44a by screwing, and the shielding member 46 surrounds the interlocking member 48 so that the interlocking member 48 is not exposed to the outside. It is screwed into the liner 44a. In addition, the cam 40 allows the body to pass through the vertical portion 30, the interlocking member 48, and the shielding member 46, so that the tip portion of the cam 40 is cam on the interlocking member 48 side. The rear end of the 40 is provided to be located on the vertical portion 30 side. Here, the front end portion of the cam 40 is fixedly installed on the support member 50 supported in the interlocking member 48, and one end portion of the cam 40 is pin-coupled with the interlocking member 48 by a pin 49. have.

3 to 6 illustrate a state in which the storage door 44 is not tilted. In this state, as shown in FIG. 3, the vertical portion 30 and the shielding member 46 are in close contact with each other. In other words, the storage space door 44 completely seals the storage space. 6, one side of the cam 40 is in contact with the roller 36.

As such, the reason why one side of the cam 40 can be kept in contact with the roller 36 without sagging downward of the cam 40 is because of the spring 54. That is, the spring 54 is set in a slightly compressed state without the storage door 44 being tilted. The spring 54 exerts a restoring force on the acting portion 50a of the support member 50, and the restoring force applied to the acting portion 50a is transmitted to the distal end of the cam 40 so that the distal end of the cam 40 is downward. Will receive the power to act. As a result, the cam 40 receives a force lifted upwardly, and the cam 40 can move in contact with the roller 36.

And, since the spring 54 is applying a restoring force downward to the support member 50 in a state in which the storage space door 44 is not tilted, the storage space door 44 is more tightly adhered to the refrigerator body. do.

On the other hand, when the user takes out a door basket (not shown) provided on the back of the storage door 44 and drinks stored in the storage space, the user does not pull the storage space door 44 forward for power saving or convenience. By tilting the upper part only slightly, the user feels the necessity to take out the beverage or the like through the opened part.

At this time, when the user pulls the handle (not shown) provided on the upper front of the storage door 44, the storage door 44 rotates in a curve around the hinge portion 42. In addition, the cam 40 moves in close contact with the outer circumferential surface of the roller 36 as the storage space door 44 rotates, and the front end of the cam 40 is lifted upward. As a result, the working space 50a of the support member 50 is in a state of receiving more compression than when the storage door 44 is not tilted.

As such, the state in which the user completely tilts the storage door 44 is illustrated in FIG. 7. The storage door 44 is no longer tilted because the movement restricting portion 41 of the cam 40 is hooked on the wear preventing pin 38 provided on the receptacle 32.

In addition, the wear preventing pin 38 prevents the movement restricting portion 41 from hitting the roller 36, thereby preventing incomplete sealing of the storage space door 44 due to wear of the roller 36. . However, if the wear preventing pin 38 is not provided and the movement restricting portion 41 strikes the roller 36, wear occurs on the roller 36 as described above, and thus the roller 36 is relatively on the side of the roller 36. One side of the cam 40 in contact with the upper portion is relatively upward, and the other side of the cam 40 fixed to the support member 50 is lowered downward.

As a result, the storage door 44 does not stand straight and the storage space is incompletely sealed with the upper end slightly tilted. As a result, if the structure is not provided with the wear protection pin 38, cold air is leaked to cause the freshness of the stored matter and the problem of power loss, the movement of the cam 40 is incomplete due to the wear of the roller 36 This will interfere with the smooth tilting of the storage door 44.

This problem is solved by the anti-wear pin 38 according to the present invention as described above.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

The tilting structure of the door for a refrigerator according to the present invention as described in detail above has the following effects.

That is, the present invention enables a smooth tilting of the storage door by means of a spring acting as a damping and a cam applying continuous compression to the spring. Accordingly, in the present invention, the user can make the tilting of the storage space door more convenient, thereby improving the reliability of the product.

In addition, in the present invention, when the cam strikes the wear preventing pin, the force and the moment transmitted to the cam are buffered by the spring, so that the cam is firmly supported by the interlocking member and the supporting member.

In addition, the movement restriction portion of the cam is not struck by the roller to be hung on the wear prevention pin, thereby preventing the storage space door from incompletely sealing the storage space by the wear of the roller.

In addition, by forming the tip of the movement restriction portion that hits the wear protection pin to correspond to the shape of the outer circumferential surface of the wear protection pin, there is also an effect of preventing the breakage of the wear protection pin by evenly spreading the impact on the wear protection pin.

Claims (4)

A receptacle installed on a rear surface of the vertical part supporting the storage box located in the storage space, the receptacle rotatably supported on the upper portion thereof; An interlocking member coupled to both sides of the door liner forming an inner surface of the storage space door and interlocked with the storage space door; A cam which is coupled to the interlocking member while receiving an elastic force by a spring and the other side is guided to be in contact with the outer circumferential surface of the roller while operating with the storage space door; Tilting structure of the door for the refrigerator characterized in that it comprises a; is installed in the receptacle and the wear-resistant pin to regulate the tilting range of the storage space door by selectively moving the movement control portion of the cam according to the tilting of the storage space door . The method of claim 1, The wear prevention pin is provided at the rear of the roller tilting structure of the door for a refrigerator, characterized in that the first hit the abrasion prevention pin before the movement restriction portion hit the roller. The method according to claim 1 or 2, Tilting structure of the door for a refrigerator, characterized in that the front end of the movement restriction portion is formed to correspond to the outer peripheral surface shape of the wear preventing pin. The method of claim 3, One side of the cam is pin-coupled to the interlocking member, the front portion of the pin coupling portion of the cam is fixed to a support member positioned inside the interlocking member, and the rear portion of the pin coupling portion of the cam is an outer circumferential surface of the roller. Is installed to move in contact with, A spring is installed to surround the support member, and the spring is selectively compressed or restored by an action of the support member according to the movement of the cam.

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