KR20200140556A - Refrigerator - Google Patents

Abstract

According to an embodiment of the present invention, a refrigerator comprises: a cabinet having a storage space therein; a door including a door part for opening and closing the storage space by insertion and withdrawal, and a drawer part connected to the door part and having an accommodating space; a rail for connecting the door and the cabinet, and moving the door in and out; and a lifting device provided in the drawer part and lifting at least a part of the drawer part. The lifting device includes: a lower frame for forming a bottom surface of the lifting device, and fixed; an upper frame disposed to be separated from an upper side of the lower frame; and a scissor assembly for connecting the lower and upper frames and lifting the upper frame. The scissor assembly includes: a plate-shaped plate unit rotationally mounted on the lower frame and supporting the upper frame; and a rod unit including a pair of rods coupled to cross the plate unit, rotationally coupled to the upper frame, and supporting the lower frame. Accordingly, stability of use is secured.

Description

Refrigerator {Refrigerator}

The present invention relates to a refrigerator.

In general, refrigerators are home appliances that allow low-temperature storage of food in an internal storage space that is shielded by a door. To this end, the refrigerator is configured to store the stored food in an optimal state by cooling the interior of the storage space using cold air generated through heat exchange with the refrigerant circulating through the refrigeration cycle.

Recent refrigerators are gradually becoming larger and multifunctional in accordance with changes in dietary life and the trend of high-end products, and refrigerators with various structures and convenience devices that enable users' convenience and efficient use of internal space are being released. .

The storage space of the refrigerator can be opened and closed by a door. In addition, it may be classified into various types of refrigerators according to the arrangement of the storage space and the structure of the door opening and closing the storage space.

Refrigerator doors can be classified into a rotating door in which the storage space is opened and closed by rotation, and a drawer door in which the storage space is opened and closed.

In addition, the drawer door is often disposed in the lower area of the refrigerator. When the drawer door is disposed in the lower area of the refrigerator, the waist must be bowed to take out the basket or food accommodated in the drawer door, and the basket or If the weight of the food is heavy, you may feel inconvenient to use the basket or cause injury.

In order to solve this problem, various structures in which a drawer-type door can be elevated have been developed.

Representatively, U.S. Patent No. 9,377,238 discloses a refrigerator provided with a lifting mechanism for lifting a bin provided in a refrigerator compartment.

However, in such a prior art, a lifting mechanism for lifting and lowering has a structure in which the lifting mechanism is disposed on the outside of the bin and is exposed, and this may cause serious safety problems. In addition, there is a problem of poor appearance due to the structure of the lifting mechanism exposed to the outside.

In addition, since the lifting mechanism has a single structure, the lifting load is limited, and if food with a heavy weight is stored, it is impossible to move up or down, or there is a problem in that the required performance cannot be satisfied.

In addition, since the lifting mechanism is composed of a plurality of rod-shaped arm structures, when a large load is applied, the arm may be damaged, and there is a problem in that the normal operation of the lifting mechanism is impossible.

An embodiment of the present invention is to provide a refrigerator in which an electrical device for lifting is provided inside a door part, and a mechanical device for lifting is provided in a drawer part, respectively.

An object of the present invention is to provide a refrigerator having a structure capable of effectively lifting and lowering a high load storage object.

An object of the present invention is to provide a refrigerator with improved strength of a scissor assembly constituting an elevator.

An embodiment of the present invention is to provide a refrigerator that facilitates the operation of a scissor assembly.

An object of the present invention is to provide a refrigerator in which lifting stability is improved by a scissor assembly comprising a plate unit and a rod unit intersecting the plate unit.

A refrigerator according to an embodiment of the present invention includes a cabinet in which a storage space is formed; A door including a door portion for opening and closing the storage space by withdrawal and opening, and a drawer portion connected to the door portion and forming a storage space; A rail connecting the door and the cabinet and for pulling out the door; A lifting device provided on the drawer part and for lifting at least a portion of the drawer part, wherein the lifting device comprises: a lower frame that forms a bottom surface of the lifting device and is fixed; An upper frame spaced apart from the upper frame of the lower frame; And a scissor assembly connecting the lower frame and the upper frame and raising and lowering the upper frame, wherein the scissor assembly includes: a plate-shaped plate unit rotatably mounted to the lower frame and supporting the upper frame; It includes a pair of rods intersecting with the plate unit, is rotatably coupled to the upper frame, and may include a rod unit supporting the lower frame.

The scissors assembly may be provided with a pair on both sides.

The lifting device may be provided inside the storage space.

The door part may be provided with a driving device connected to the lifting device to provide power for lifting the lifting device.

A lever-side connection part is formed in the driving device, a scissor-side connection part is formed in the plate unit, and the scissor-side connection part may pass through the front surface of the drawer and be connected to the driving device.

A drawer opening is formed on the front of the drawer corresponding to the lever-side connection part, and the scissor-side connection part may be detached from the lever-side connection part by entering and leaving the drawer opening.

The scissor side connection part may be formed to protrude from the plate unit.

The plate unit may be formed of an aluminum alloy material.

A polygonal reinforcing groove may be continuously formed on the entire surface of the plate unit.

The plurality of adjacent reinforcing grooves may be spaced apart at equal intervals.

The plate unit may have a rod through hole through which the load unit passes.

A rod rotation shaft to which the rod unit is rotatably coupled may protrude from the rod through hole.

Rod sliders protruding laterally are formed at lower ends of both side surfaces of the load unit, and a rod guide for accommodating the rod slider may be provided on the lower frame.

The rod opening may be formed to have a width capable of simultaneously receiving the rod unit and the rod guide when the scissor assembly is operated.

Plate sliders protruding laterally are formed on upper ends of both side surfaces of the plate unit, and a rod guide for accommodating the rod slider may be provided on the upper frame.

A load roller rotating in contact with the inner surface of the lower frame may be provided at both lower ends of the load unit, and a plate roller rotating in contact with the inner surface of the upper frame may be provided at both upper ends of the plate unit.

The upper frame and the lower frame are formed in a plate shape, and the lower frame includes a lower supporting part protruding along a moving path of the load roller and in line contact with the load roller; The upper frame may include an upper supporting part protruding along a moving path of the plate roller and in line contact with the plate roller.

The upper frame and the lower frame are formed in a plate shape, and the circumference is bent to accommodate the scissors assembly in a state in which the upper frame is lowered.

The load unit includes: a first rod and a second rod penetrating both sides of the plate unit; It may include an upper connecting rod and a lower connecting rod connecting upper and lower ends of the first rod and the second rod.

A pair of rod through holes opening in the extending direction of the first rod and the second rod are formed at both sides of the plate unit so as not to interfere with the first rod and the second rod when the scissor assembly is operated, and the first The rod and the second rod may be axially coupled inside the pair of rod through holes.

In the refrigerator according to the proposed embodiment, the following effects can be expected.

A refrigerator according to an embodiment of the present invention is configured to allow a part of the storage space inside the drawer door to be lifted or lowered while the drawer door is pulled out. In addition, a driving device composed of an electric device for providing power is provided inside the door part, and the lifting device for lifting is provided inside the drawer part so that both the driving device and the lifting device are not exposed to the outside. It is possible to ensure stability and improve the appearance.

In addition, it is possible to minimize the loss of storage capacity of the drawer part by arranging the driving device that occupies a significant part of the entire configuration in the door part. In addition, the lifting device or in a lowered state has an advantage of securing a storage capacity in the compartment by having a structure that is compactly folded and accommodated.

In addition, the elevating device includes a lower frame and an upper frame, and a scissor assembly connecting the lower frame and the upper frame, and the scissor assembly is provided with a pair on both sides of the scissor assembly to operate at the same time.

Therefore, the lifting device has the advantage of supporting a higher load and ensuring stability and durability of the lifting operation.

In addition, the driving device may include one motor, and power provided from one motor may be transmitted to both sides of the scissor assembly so that both sides of the scissor assembly are operated simultaneously. Therefore, even if an offset load is applied to the lifting device, both sides of the upper frame may be elevated in a horizontal state, thereby further improving the stability of the lifting operation.

In addition, the scissor assembly constituting the lifting device has a structure in which a plate unit having a plate shape and a rod unit including a pair of rods are coupled to cross each other. Accordingly, there is an advantage in that the strength of the scissors assembly for elevating the upper frame can be improved and durability can be remarkably improved.

In addition, a rod through hole may be formed in the plate unit, and the rod unit may be rotatably coupled inside the rod through hole. In addition, the rod through hole is formed to extend so as not to interfere with the rod unit during operation of the lifting device, thereby improving the strength of the scissor assembly and ensuring operability at the same time.

Further, the plate unit is formed of an aluminum alloy material having high strength, so that even when a large load is applied, the lifting device may not be damaged, and there is an advantage of supporting the overall load applied to the lifting device.

Particularly, when the lifting device is driven, the scissor side connection, which concentrates the torque by rotation, is formed on the plate unit, so that a greater force can be transmitted to the lifting device, and the scissor assembly is damaged even if a load concentration situation occurs. Can be avoided.

In addition, a reinforcing groove is formed in the plate unit as a whole, so that the strength of the plate unit can be further improved, and an effect of further improving the durability of the lifting device can be expected.

In addition, there is an advantage in that it is possible to lift a heavier storage object and to ensure stability of operation.

In addition, the upper frame and the lower frame are formed in a plate shape, and the scissor assembly is accommodated between the upper frame and the lower frame in a state in which the lifting device is lowered, so that the lifting device is compactly configured and a storage space inside the drawer part Loss can be minimized.

Further, the upper frame and the lower frame may be provided with a plate guide and a rod guide respectively accommodating the plate slider and the rod slider to guide the sliding movement of the plate unit and the rod unit. Accordingly, there is an advantage in that the end portions of the plate unit and the rod unit do not always deviate from a set position, thereby ensuring a stable lifting operation of the lifting device, and preventing damage to the lifting device.

Further, a lower supporting portion and an upper supporting portion in contact with the plate roller and the load roller are formed to extend along the movement paths of the plate roller and the load roller, respectively, on inner surfaces of the upper frame and the lower frame. In addition, the lower supporting part and the upper supporting part are processed so that the upper frame and the lower frame of the plate protrude so that the plate roller and the road roller are in line contact, so that the operation of the scissor assembly can be made more smoothly and stably. have.

1 is a front view of a refrigerator according to an embodiment of the present invention.
2 is a cross-sectional view schematically showing an elevating state of a drawer door according to an embodiment of the present invention.
3 is a perspective view of the drawer door in which the container is separated.
4 is an exploded perspective view of the drawer door as viewed from the front in which the drawer part and the door part are separated.
5 is an exploded perspective view of a state in which the lifting device is separated from the drawer door.
6 is a rear view of the door part.
7 is a rear perspective view of the door part with the door cover removed.
8 is a cross-sectional view showing a connection state between a driving device and an elevator device according to an embodiment of the present invention.
9 is a perspective view of the driving device.
10 is a perspective view showing the internal structure of the driving device.
11 is a partial enlarged view showing a structure in which power is transmitted to a screw of the driving device.
12 is an exploded perspective view of the drawer part.
13 is a perspective view of the lifting device.
14 is a front view of the upper frame of the lifting device in an elevated state.
15 is a side view of the upper frame of the lifting device in an elevated state.
16 is an exploded perspective view of the lifting device.
17 is a perspective view of a plate unit that is a configuration of the lifting device.
18 is a perspective view of a load unit that is a configuration of the lifting device.
FIG. 19 is a cut-away perspective view 19-19' of FIG. 13.
20 is a perspective view showing a supporting structure of the plate unit of the lifting device.
21 is an enlarged view of part A of FIG. 20.
22 is a perspective view showing the supporting structure of the plate unit of the lifting device.
23 is an enlarged view of part B of FIG. 22
24 is an enlarged view of a connection portion between the lifting device and the driving device.
25 is a perspective view of the drawer door in a closed state.
26 is a perspective view of the drawer door fully open.
27 is a cross-sectional view of the drawer door when the container of the drawer door is completely lowered.
28 is a perspective view showing the state of the driving device and the lifting device in the state of FIG. 27;
29 is a cross-sectional view of the drawer door when the container of the drawer door is completely raised.
FIG. 30 is a perspective view showing states of the driving device and the lifting device in the state of FIG. 29;

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same numerals as possible even if they are indicated 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 interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

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

1 is a front view of a refrigerator according to an embodiment of the present invention. And, Figure 2 is a cross-sectional view schematically showing the lifting state of the drawer door according to an embodiment of the present invention.

1 and 2, the refrigerator 1 may have an external shape formed by a cabinet 10 forming a storage space and a door 2 shielding the opened front surface of the cabinet 10. have.

The storage space inside the cabinet 10 may be divided into a plurality of spaces. For example, the upper space 11 of the cabinet 10 may be divided into a refrigerating chamber, and the lower space 12 may be divided into a freezing chamber. Of course, the upper space and the lower space may be divided into separate spaces maintained at different temperatures rather than a refrigerating compartment or a freezing compartment, and may be referred to as an upper space and a lower space.

The door 2 may include a rotating door 20 that opens and closes the upper space by rotation, and a drawer door 30 that opens and closes the lower space by drawing in/out. The lower space may be divided up and down again, and the drawer door 30 may include an upper drawer door 30a and a lower drawer door 30b.

In addition, the rotating door 20 and the drawer door 30 are formed of a metal material to form an exterior exposed to the front.

The present invention has been described on the basis of a refrigerator in which the rotating door 20 and the drawer door 30 are disposed together, but the present invention is not limited thereto, and all types of refrigerators provided with a drawer-type door Will be applicable. In addition, the rotary door 20 may be provided at an upper portion and may be referred to as an upper door, and the drawer door 30 may be provided at a lower portion to be referred to as a lower door.

A display 21 may be provided on one front side of the rotating door 20, and the display 21 may include a structure of a liquid crystal display or an 88-segment structure.

In addition, when the exterior of the door 2 is formed of a metal material, the display 21 may be formed such that a plurality of fine holes are perforated to display information by transmitted light.

In addition, an operation unit 22 capable of operating automatic rotation or withdrawal of the upper door 2 or the lower door 2 may be provided on one side of the rotary door 20.

The manipulation unit 22 may be provided integrally with the display 21 and may be operated by a touch method or a button method. The manipulation unit 22 may input/operate a command for the overall operation of the refrigerator 1, and may operate the drawer door 30 to move in/out or to move the drawer door 30 up or down.

An operation unit 301 may also be provided on the drawer door 30. The operation unit 301 may be provided on one side of the lower drawer door 30b positioned at the bottom of the drawer doors 30, and the operation unit 301 may be configured in a touch or button manner. Of course, the manipulation unit 301 may be configured as a sensor that detects the user's proximity or movement, or may be configured to input manipulation by the user's motion or voice.

In addition, as shown in the drawing, a manipulation device 302 is provided at the bottom of the lower drawer door 30b to output a virtual switch by irradiating an image on the bottom surface and input manipulation in a manner that allows the user to approach the area. It could be configured.

Meanwhile, the lower drawer door 30b may be automatically pulled in and out according to the manipulation of the manipulation units 22,301, and 302. In addition, food or containers provided in the lower drawer door 30b may be raised or lowered in a state in which the lower drawer door 30b is pulled out according to the operation of the operation unit 301.

In order to store food stored in the lower drawer door 30b, the lower drawer door 30b is pulled forward, and then the container 36 inside the lower drawer door 30b can be operated to lift.

On the other hand, the container 36 may have a shape corresponding to the size of the front space (see S1 in FIG. 3), and have a predetermined height so that the food stored therein is separated even when the lifting device 80 is raised. It would be desirable to be configured not to be.

By such an operation, the food or container 36 inside the drawer door 30 disposed at the lowermost position can be more easily lifted and used.

The lower drawer door 30b is automatically pulled back and forth by a pull-out motor 14 and pinion 141 provided in the cabinet 10 and a pull-out rack 34 provided on the lower surface of the lower drawer door 30. May be worn.

In addition, the container inside the lower drawer door 30b may be raised and lowered by the driving device 40 and the lifting device 80 provided in the lower drawer door 30b.

Hereinafter, configurations for the operation of the lower drawer door 30b and the lower drawer door 30b of the present invention will be described in more detail. Unless otherwise stated, the lower drawer door 30b is Let's call it a door or door.

Meanwhile, the embodiment of the present invention is not limited to the number and shape of drawer doors, and may be applied to all refrigerators provided with a drawer-type door in a lower storage space.

3 is a perspective view of the drawer door in which the container is separated. 4 is an exploded perspective view of the drawer door as viewed from the front in which the drawer part and the door part are separated. And, Figure 5 is an exploded perspective view of a state in which the lifting device is separated from the drawer door.

As shown, the door 30 has a door part 31 for opening and closing the storage space, and a drawer part 32 that is coupled to the rear surface of the door part 31 and is drawn in and out with the door part 31 It may include.

The door part 31 may be exposed to the outside of the cabinet 10 to form the exterior of the refrigerator 1, and the drawer part 32 is disposed inside the cabinet 10 to form a storage space. can do. In addition, the door portion 31 and the drawer portion 32 may be combined with each other to be withdrawn in and out of the front and rear directions.

The drawer part 32 is always located on the rear surface of the door part 31 and may form a space in which food or containers for storage are accommodated. The inside of the drawer part 32 may form a storage space that is open upward, and the outside of the drawer part 32 may have an exterior formed by a plurality of plates (391 and 392 in FIG. 12).

The plurality of plates 391 and 392 may be made of a metal material such as stainless steel, and are provided outside as well as inside of the drawer 32 so that the exposed portions of the drawer 32 have the same texture as stainless steel or stainless steel. It can be formed to have.

In a state in which the door 30 is retracted, a machine room 3 in which a compressor and a condenser constituting a refrigeration cycle may be disposed behind the door 30. Accordingly, the rear part of the drawer part 32 may have an upper end protruding more than a lower end, and the rear part of the drawer part 32 may include an inclined surface 321.

In addition, draw-out rails 33 that can guide the draw-out of the door 30 may be provided on both side surfaces of the drawer part 32. The door 30 may be mounted to the cabinet 10 so as to be able to be withdrawn and inserted by the withdrawal rail 33. The lead-in/out rail 33 may be shielded by an outer side plate 391 so as not to be exposed to the outside. The draw-out rail 33 may be configured in a rail structure that can be extended in multiple stages.

A rail bracket 331 is provided on the draw-out rail 33, and the rail bracket 331 may extend from one side of the draw-out rail 33 to both sides of the drawer part 32. In addition, the rail bracket 331 may be fixedly coupled to the interior wall of the cabinet. Accordingly, the drawer unit 32, that is, the door 30 may be mounted to the cabinet 10 so as to be retractable by the draw-out rail 33.

In addition, the draw-out rail 33 may be provided at the bottom of both side surfaces of the drawer part 32. In addition, the lower ends of both sides of the drawer part 32 are mounted in a form that is seated above the draw-out rail 33, and thus, the draw-out rail 33 may be referred to as the under rail. .

A pull-out rack 34 may be provided on the lower surface of the drawer part 32. The draw-out rack 34 may be disposed on both sides, and is connected with the drive of the draw-out motor 14 mounted on the cabinet 10 to enable automatic draw-out of the door 30. That is, when the operation unit 22 and 301 inputs an operation, the withdrawal motor 14 is driven so that the door 30 can be withdrawn according to the movement of the withdrawal rack 34. At this time, the door 30 can be stably pulled in and out by the pull-out rail 33.

Of course, the drawer part 32 may not be provided with a draw-out rack 34, and the user is configured to directly draw in/out the door 30 by holding and pushing or pulling one side of the door part 31. It will be possible.

Meanwhile, the inside of the drawer unit 32 may be divided into a front space S1 and a rear space S2. The front space S1 may include a lifting device 80 that is lifted up and down, and a container 36 that is seated in the lifting device 80 and lifted together with the lifting device 80.

The container 36 is shown in the form of a basket with an open top, but may have a closed box structure such as a kimchi container, and a plurality of containers may be stacked or disposed side by side.

In addition, when the door 30 is withdrawn, the entire drawer unit 32 cannot be pulled out of the storage space due to the restriction of the pulling distance of the door 30, and at least the front space S1 is It is drawn out of the storage space and all or part of the rear space S2 is located inside the storage space inside the cabinet 10.

In such a structure, the withdrawal distance of the door 30 may be limited by the draw-out rack 34 or the draw-out rail 33, and the longer the draw-out distance is applied to the door 30 in the withdrawn state. This is because it is difficult to maintain a stable state due to an increase in the losing moment, and deformation or damage of the draw-out rail 33 or the draw-out rack 34 may be caused.

Inside the front space (S1), a lifting device 80 and a container 36 are accommodated, and the lifting device 80 is lifted up and down, while the food or container 36 seated in the lifting device 80 ) Can be raised and lowered together. In addition, the lifting device 80 may be provided under the container 36, and when the container 36 is mounted, the lifting device 80 may be covered by the container 36, thus Any configuration of the lifting device 80 is not exposed to the outside.

A separate drawer cover 37 may be provided in the rear space S2. The front space S1 and the rear space S2 may be partitioned by the drawer cover 37. When the drawer cover 37 is mounted, the front and upper surfaces of the rear space S2 are shielded so that the unused space is not exposed to the outside.

By attaching the drawer cover 37, the rear space S2 is covered when the door 30 is withdrawn, and only the front space S1 is exposed when the door 30 is pulled out, thereby providing a cleaner appearance. It will be able to provide. In addition, the rest of the space except for the space in which the lifting device 80 and the container 36 are mounted is covered so that a problem such as a food dropping or an object being caught in a gap during lifting may not occur.

When the drawer cover 37 is separated, it becomes accessible to the rear space S2, and food can be stored in the rear space S2. In order to utilize the rear space S2, a separate pocket or a container corresponding to the shape of the rear space may be disposed in the rear space S2.

And, in order to utilize the entire space inside the drawer part 32, the lifting device 80 inside the drawer part 32 can be simply detachably mounted, and the lifting device 80 and the drawer cover 37 By separating the drawer unit 32, the entire inner space may be utilized.

Components mounted on the drawer part 32 may be shielded by the plates 391 and 392, and external and internal appearances of the drawer part 32 may be clearly visible.

Meanwhile, the door part 31 and the drawer part 32 constituting the door 30 may have a structure that can be separated and coupled to each other. Assembly workability and serviceability may be improved through the detachable structure of the door part 31 and the drawer part 32.

The rear surface of the door part 31 and the front surface of the drawer part 32 may be coupled to each other, and when the door part 31 and the drawer part 32 are combined, the power for lifting the lifting device 80 It can be configured to provide.

The driving device 40 for lifting the lifting device 80 may be disposed on the door part 31, and the door part 31 and the drawer part 32 may be selectively connected. In particular, the driving device 40 provided in the door part 31 may include components operated by input of power and components for transmitting power to the lifting device 80. Accordingly, when the service of the driving device 40 is required, the door part 31 can be separated to take action, and only the door part 31 can be replaced to take a simple action.

The door part 31 and the drawer part 32 may be coupled by a pair of door frames 316 provided on both sides.

In addition, when the door part 31 and the drawer part 32 are combined, a part of the lifting device 80 is provided on the front of the drawer part 32 so that the driving device 40 and the lifting device 80 can be connected. A drawer opening 35 through which is exposed may be formed.

A scissor-side connection part 842, which is a rotation axis of the lifting device 80, may be exposed inside the drawer opening 35. Accordingly, when the scissor side connection part 842 is connected to the driving device 40, the lifting device 80 may be in an operable state.

In addition, the drawer openings 35 may be formed at both front and left ends of the left and right drawer portions 32. In addition, between the drawer openings 35, a plurality of ventilation holes 381 may be formed to allow air to flow inside and outside the drawer part 32. The drawer opening 35 and the ventilation hole 381 may be formed at a position lower than the height of the lifting device 80, and thus, when the lifting device 80 is mounted, the drawer opening 35 and the ventilation hole ( 381) can be masked.

On the other hand, the lifting device 80 has a structure that can be separated from the drawer 32 according to the user's operation. That is, when the volume inside the drawer part 32 is increased or the lifting function is not used, the lifting device 80 is lifted and separated from the inside of the drawer part 32.

On the other hand, the door part 31 is formed to substantially open and close the storage space of the cabinet 10 and at the same time form a front exterior of the refrigerator 1.

The door part 31 may include an outer case 311 forming a part of the front and circumferential surfaces, and a door liner 314 forming a rear surface. In addition, an insulating material may be filled inside the door part 31 between the outer case 311 and the door liner 314.

Hereinafter, the door portion 31 constituting the door 30 will be described in more detail with reference to the drawings.

6 is a rear view of the door part. And, Figure 7 is a rear perspective view of the door portion of the door cover removed.

As shown, a driving device 40 for operating the lifting device 80 may be provided inside the door part 31. The driving device 40 is disposed inside the door part 31, but is not buried in the heat insulating material, but is provided inside the space formed by the door liner 314, and the door cover 315 It may be configured so as not to be exposed to the outside by being shielded by.

Further, the door liner 314 may be formed to further mount electrical components including a door light 318 for illuminating the interior of the cabinet. The door light 318 may be long disposed in the horizontal direction from the left to the right of the rear surface of the door 30. The door light 318 is configured such that a plurality of LEDs and light irradiated from the LED are directed toward the inside of the door 30, particularly the drawer part 32, and the door 30 is pulled out and opened. In the state, the inside of the drawer 32 is illuminated.

The door cover 315 is for forming a rear exterior of the door part 31 and shields the driving device 40 mounted on the door part 31. The door cover 315 may be formed in a plate shape, and may shield the rest of the driving device 40 except for the lever-side connection part 422 when the driving device 40 is mounted.

Meanwhile, cover openings 315a may be formed at both sides of the lower end of the door cover 315. The cover openings 315a are formed on both sides of the door part 31 corresponding to the rotation axis of the lever 42 and the lifting device 80. In addition, the cover opening 315a may be formed to have a size corresponding to a radius of rotation of the lever-side connecting portion 422 so as not to interfere with the rotating lever-side connecting portion 422.

The cover opening 315a exposes the drawer-side connection part 422 of the lever 42, which is a component of the driving device 40, to the drawer-side connection part 422 through the cover opening 315a. Access becomes possible. In addition, the cover opening 315a may be located at a position facing the drawer opening 35.

Therefore, when the door part 31 and the drawer part 32 are combined, the cover opening 315a and the drawer opening 35 can communicate with each other, and thus, the cover opening 315a and the drawer opening Through 35, the drawer-side connection part 422 and the scissor-side connection part 842 of the lifting device 80 may be coupled. That is, the driving device 40 and the lifting device 80 may be connected to each other, and the lifting device 80 may be raised or lowered according to the operation of the driving device 40. In addition, it is possible to separate only the lifting device 80 through the separation of the drawer side connection part 422 and the scissor side connection part 842 in a state in which the door part 31 and the drawer part 32 are coupled. will be.

On the other hand, in the center of the lower end of the door cover 315, a cable hole 315e through which cables connected to electrical components such as the driving device 40 provided in the door part 31 and the door light 318 enter and exit is further provided. Can be formed. Wires entering and leaving through the cable hole 315e may pass under the drawer 32 and be connected to the cabinet 10.

A door gasket 317 may be provided along the rear circumference of the door part 31, and when the door 30 is closed, the door gasket 317 may be sealed in contact with the front of the cabinet 10. have.

The driving device 40 may be shielded by the door cover 315 and disposed inside the door part 31. The driving device 40 is connected to the lifting device 80, and the power of the driving device 40 may be transmitted to the lifting device 80. At this time, the driving device 40 simultaneously transmits power to both the left and right sides of the lifting device 80 so that the lifting device 80 is not inclined or biased to one side under any circumstances, and the left and right sides are horizontally elevated and lowered. You can do it.

The driving device 40 includes a motor assembly 60, a pair of screw units 50 disposed on both sides of the motor assembly 60, and a pair of levers connected to each of the screw units 50 (42) may be included. In addition, the screw unit 50 may include a screw 52 and a screw holder 56 which is penetrated by the screw 52 and is raised and lowered along the screw unit 50.

Meanwhile, the lever 42 has a lever-side connection part 422 formed at one end of the lever extension part 421, and the lever-side connection part 422 is rotatably fixed to the rear surface of the door part 31. Further, a lever hole 423 through which the holder fastening member 564 is fastened may be formed at the other end of the lever extension 421.

The lever hole 423 is formed in a long hole shape, guides the movement of the holder fastening member 564, and allows the holder fastening member 564 to be fastened to the screw holder 56 at the same time. Accordingly, the lever 42 is rotated by the screw holder 56 that is raised and lowered when the screw 52 is rotated. The driving device 40 will be described in more detail below.

Hereinafter, the structure of the driving device 40 will be described in more detail.

8 is a cross-sectional view showing a connection state between a driving device and an elevator device according to an embodiment of the present invention. And, Figure 9 is a perspective view of the driving device. And, Figure 10 is a perspective view showing the internal structure of the driving device. And, Figure 11 is a partial enlarged view showing a structure in which power is transmitted to the screw of the driving device.

As shown, the motor assembly 60 may be located in the center portion in the left and right direction of the door portion 31. Further, it may be configured to enable the operation of the screw units 50 and 50a and the lever 42 on both sides by driving the motor assembly 60 including one driving motor 64.

Particularly, the motor assembly 60 may adjust the amount of deceleration and transmitted force through a combination of a plurality of gears.

In addition, the motor assembly 60 has a structure in which the drive motor 64 and gears are arranged vertically in order to minimize a space that is depressed when mounted on the door part 31, and in particular, the motor assembly 60 It may be formed to widen the width in the left and right directions to minimize the thickness of the material and to minimize the thickness in the front and rear directions.

In addition, the drive motor 64 constituting the motor assembly 60 may protrude toward the drawer part 32 to minimize a depression depth of the door part 31 to ensure thermal insulation performance.

The drive motor 64 provides power for the lifting of the lifting device 80 and may be configured to rotate forward and backward. Accordingly, when the lifting signal of the lifting device 80 is input, it is rotated forward and backward, thereby providing power for lifting the lifting device 80. In addition, the drive motor 64 may be stopped when a load of the driving motor 64 or a stop signal is input by detection of a sensor.

The motor assembly 60 includes a motor case 61 in which the driving motor 64 is installed, and a motor cover 62 coupled to the motor case 61 and covering the driving motor 64. I can.

The rotation axis of the drive motor 64 may protrude from the motor case 61 toward the opposite side of the motor cover 62. In addition, the motor assembly 60 may further include a power transmission unit for transmitting the power of the driving motor 64. The power transmission unit may be located on the opposite side of the driving motor 64 with respect to the motor case 61.

In addition, the power transmission unit may be formed of a combination of a plurality of gears, and may be shielded by a cover member 66 mounted on the opposite side of the drive motor 64.

The power transmission unit may include a driving gear 651 connected to the shaft of the driving motor 64 passing through the motor case 61. The power transmission unit may further include a first transmission gear 652 meshed with the driving gear 651 from a lower side of the driving gear 651.

The first transmission gear 652 may be, for example, a multi-stage gear. As an example, the first transmission gear 652 includes a first gear 652a meshed with the driving gear 651 and a second gear 652b having a diameter smaller than that of the first gear 652a. Can include. Each of the first gear 652a and the second gear 652b may be a spur gear.

The power transmission unit may further include a second transmission gear 653 meshing with the first transmission gear 652. The second transmission gear 653 may mesh with the first transmission gear 652 from a lower side of the first transmission gear 652. The second transmission gear 653 includes a first gear 653a meshing with the second gear 652a of the first transmission gear 652, and a first gear having a larger diameter than the first gear 653a. It may include 2 gears 653b.

Each of the first gear 653a and the second gear 653b of the second transmission gear 653 may be a spur gear. In addition, the second gear 653b of the second transmission gear 653 may be located below the first gear 652a of the first transmission gear 652. Accordingly, an increase in the front and rear width of the driving device 60 can be prevented by the first transmission gear 652 and the second transmission gear 653.

The power transmission unit may further include a third transmission gear 654 meshed with the second transmission gear 653. The third transmission gear 654 may mesh with the second gear 653b under the second gear 653b of the second transmission gear 653. The third transmission gear 654 may be a spur gear. A portion of the third transmission gear 654 may be disposed to overlap the second transmission gear 653 in the front-rear direction.

A gear shaft for rotatably supporting the plurality of transmission gears may be provided in the motor case 61.

The power transmission unit may include a pair of cross gears 655 and 656 meshed with the third transmission gear 654. The pair of crossover gears 655 and 656 are arranged to be spaced apart from each other in the left and right direction, and the rotation center is lower than the rotation center of the third transmission gear 654 to be meshed with the third transmission gear 654. have.

Each of the crossed gears (655, 656) is a spur gear (655a, 656a) and a helical gear form so that the cross gears (655, 656) can mesh with the third transmission gear (654). It may include first helical gear units 655b and 656b.

In addition, the rotation center lines of the cross gears 655 and 656 spaced apart from each other may extend horizontally to each other.

The power transmission unit may further include a pair of second helical gear units 657 and 657a meshing with each of the cross gears 655 and 656.

The second helical gear parts 657 and 657a may mesh with the first helical gear parts 655b and 656b. The rotation center lines of the second helical gear units 657 and 657a may be disposed to cross the rotation center lines of the cross gears 655 and 656. Accordingly, the first helical gear units 655b and 656b and the second helical gear units 657 and 657a are intersected with each other, and may be configured to be engaged with each other to transmit rotation.

The rotation center lines of the cross gears 655 and 656 may extend in the front-rear direction, and the rotation center lines of the second helical gear units 657 and 657a may extend in the vertical direction. Further, the rotation center lines of the second helical gear units 657 and 657a disposed on both left and right sides may be inclined in a direction that is further away from each other toward the upper side.

As described above, the use of a pair of crossed helical gears has the advantage that the power transmission direction can be easily switched and the structure for power transmission becomes compact. In particular, even when a large force is transmitted for the lifting of the lifting device 80, a large noise is not generated.

The pair of screw units 50 and 50a may be disposed on both left and right sides of the motor assembly 60.

The pair of screw units (50, 50a) are disposed on both left and right sides of the inside of the door part (31), and the pair of screw units (50, 50a) differ only in their mounting positions, and their structure and shape Are the same.

Power of the driving motor 64 may be transmitted from the lower side of the screw units 50 and 50a.

The screw units 50 and 50a on both sides may be formed to be symmetrical with respect to the motor assembly 60. Accordingly, the motor assembly 60 may be disposed between the screw units 50 and 50a positioned on both sides, and the screw units 50 and 50a disposed on both sides are the distance between the top and bottom. Can be arranged to get closer and closer.

The screw units 50 and 50a may include screws 52 and 52a that are rotated by receiving power from the driving motor 64. The screws 52 and 52a may be inclined to extend in a vertical direction, with an upper end facing the outside and a lower end facing the outside.

The screws 52 and 52a may be connected to the second helical gear units 657 and 657a. That is, the screws 52 and 52a may be rotated together when the second helical gear units 657 and 657a are rotated.

For example, an insertion portion may be formed in the second helical gear portions 657 and 657a, and an accommodation groove in which the insertion portion is accommodated may be formed in the screw 52.

Accordingly, the screws 52 and 52a are also disposed to be symmetrical on both left and right sides with respect to the motor assembly 60, and may be disposed obliquely on the same center line as the center line of the second helical gear units 657 and 657a. . Accordingly, the screws 52 and 52a on both sides of the left and right sides have an arrangement that is farther away from each other as it goes upward.

The screw units 50 and 50a may further include screw holders 56 and 56a through which the screws 52 and 52a are coupled.

The screw holders 56 and 56a may be moved vertically along the screws 52 and 52a when the screws 52 and 52a are rotated. In addition, the lever 42 may be coupled to the screw holders 56 and 56a. When the screw holders 56 and 56a are moved, the lever 42 may be rotated.

In detail, a holder through hole 561 is formed in the center of the screw holders 56 and 56a. The holder through-hole 561 is formed to pass through the screw holders 56 and 56a, and is inserted and mounted so that the screws 52 and 52a pass through the holder through-hole 561. A thread coupled to the screw may be formed on the inner side of the holder through hole 561. Accordingly, when the screws 52 and 52a are rotated, the screw holders 56 and 56a are movable along the screws 52 and 52a.

In addition, guide holes 562 are formed on both left and right sides of the holder penetrating portion 561. The guide hole 562 is a portion through which the guide bars 53 and 54 to be described below pass, and the screw holders 56 and 56a may be moved along the guide bars 53 and 54.

The guide bars 53 and 54 may be formed in a round bar shape, and may be formed of a metal material to stably support the screw holders 56 and 56a.

A bearing is provided on the inner surface of the guide hole 562 to facilitate the movement of the screw holders 56 and 56a. Further, although not shown in detail, a sleeve-shaped lubricating member may be provided in the guide hole 562 through the guide bars 53 and 54. The lubricating member may be formed of engineering plastic or a material that reduces friction, thus making it easier to move the screw holders 56 and 56a and preventing noise from being generated. Of course, if necessary, the screw holders 56 and 56a themselves may be formed of an engineering plastic material.

Since a pair of the guide bars 53 and 54 are configured to pass through the guide hole 562, the screw holders 56 and 56a do not flow left and right, and a stable lift is possible. In particular, stable lifting is possible even in a situation where a heavy load is applied to drive the lifting device 80, and noise is not generated.

In addition, a magnet 563 may be provided in the screw holder 56a. As an example, a magnet mounting groove 563a into which a magnet is pressed may be formed in the screw holder 56a, and the magnet 563 may be inserted into the magnet mounting groove 563a.

The magnet 563 is for detecting the position of the screw holder 56a, and when the screw holder 56a is located at the lowest or upper end of the screws 52, 52a, a lift detection device to be described below. 90 will be able to detect this. That is, whether the magnet 563 mounted on the screw holder 56a is sensed, it is possible to determine the completion of the ascending and descending of the lifting device.

Further, although not shown in detail, a holder fastening member 564 may be mounted on the opposite side of the rear surface of the screw holder 56a on which the magnet 563 is provided, that is, the front surface of the screw holder.

The holder fastening member 564 is for connecting the lever 42 and the screw holders 56 and 56a, and may be fixedly mounted to the screw holders 56 and 56a. That is, the holder fastening member 564 may be coupled to the screw holders 56 and 56a while passing through the lever 42. The lever 42 may include a rectangular slot 426 so that the holder fastening member 564 does not interfere during the rotation of the lever 42.

Since the screw units 50 and 50a are disposed on both left and right sides, extension lines of the screws 52 and 52a on both left and right sides may cross outside of the driving device 40.

The lever 42 connects the screw holders 56 and 56a and the lifting device 80, and both ends may be coupled to the screw holders 56 and 56a and the lifting device 70, respectively.

The screw units 50 and 50a may further include a housing 51 accommodating the screws 52 and 52a.

The housing 51 forms an outer shape of the screw units 50 and 50a, and forms a space in which screws 52 and 52a and screw holders 56 and 56a can be accommodated, and is opened. The portion may be shielded by a cover member 66 to be described later.

The housing 51 may be formed by bending a plate-shaped metal material or may be formed of a plastic material.

The housing 51 may include a first accommodating portion 511 accommodating the screws 52 and 52a and a second accommodating portion 512 accommodating the second helical gear portions 657 and 657a. have.

The first accommodation part 511 and the second accommodation part 512 may be partitioned by a partition wall 513. The second accommodating part 512 is located below the first accommodating part 511.

Part of the crossover gears 655 and 656 may be accommodated in the second accommodating part 512. That is, the crossover gears 655 and 656 and the second helical gear parts 657 and 657a may be connected within the second receiving part 512.

The lower side of the screw 52, 52a penetrates the partition wall 513, and the second helical gear portions 657, 657a are coupled to the screws 52, 52a that have penetrated the partition wall 513 do.

One or more guide bars 53 and 54 for guiding the rise of the screw holders 56 and 56a may be provided in the housing 51. The one or more guide bars 53 and 54 extend in parallel with the screws 52 and 52a in a state spaced apart from the screws 52 and 52a.

A plurality of guide bars (53, 54) are provided in the housing (51) so that the screw holders (56, 56a) are not inclined to either right or left around the screws (52, 52a), the plurality of guides The screw 52 may be positioned between the bars 53 and 54.

The motor case 61 and the pair of housings 51 may be integrally formed. In addition, a single cover member 66 may cover the motor case 61 and the pair of housings 51.

That is, the cover member 66 is fastened to the motor case 61 to cover the power transmission unit, and is fastened to the pair of housings 51, the screw 52, 52a, the guide bar 53, 54), the screw holders 56 and 56a can be covered.

Of course, if necessary, the cover member 66 may be composed of a plurality of parts respectively shielding the power transmission unit and the screw units 50 and 50a to be configured to open and close each independently.

In the present embodiment, since the driving device 40 exists in the form of a single module, the driving device 40 is compact, so that the driving device 40 can be easily installed on the door part 31.

In addition, since a single cover member 66 covers the motor case 61 and the pair of housings 51 together, when the cover member 66 is separated, it is easily placed inside the power transmission unit or the housing 51. There is an advantage of being able to access, and service is easy.

Meanwhile, a lift detection device 90 may be provided in the screw unit 50a on one side of the screw units 50 and 50a on both left and right sides. Since the left and right screw units 50a are simultaneously operated by one motor assembly 60, even if the lifting detection device 90 is provided only on one screw unit 50a, the operation of the lifting device 80 is effectively performed. Can be detected. Accordingly, the lift detection device 90 may be provided in either of the left and right screw units 50 and 50a.

The elevating detection device 90 is for determining whether the elevating device 80 has been elevated or not, and determines whether the elevating apparatus 80 has elevated or descended based on the operation of the driving device 40.

The lift detection device 90 may be mounted on the cover member 66 and may be vertically disposed along the screw unit 50a.

The lift detection device 90 may include a pair of detection sensors 92 and 93. As the detection sensors 92 and 93, a sensor that detects the magnet 563 may be used. The detection sensor may be a Hall sensor that detects the position of a magnet. Of course, other sensors or devices for sensing the magnet 563 may be provided in place of the Hall sensor as needed.

In addition, in place of the magnet 563 and the Hall sensor, another configuration or device capable of detecting a specific position of the screw holder 56a may be used.

One of the detection sensors 92 and 93 is mounted at a position corresponding to the position of the magnet 563 when the lifting device 80 is completed, and the magnet when the lifting device 80 is finished descending The other may be mounted at a position corresponding to the position of 563. Accordingly, when any one of the pair of detection sensors 92 and 93 recognizes the magnet, the lifting device 80 determines that the ascending or descending is completed.

Hereinafter, the structure of the drawer part 32 will be described.

12 is an exploded perspective view of the drawer part.

As shown, the drawer part 32 is provided on the inside of the drawer body 38 and the drawer body 38 to form the overall shape of the drawer part 32 to lift the container and food. It may include a lifting device 80 and a plurality of plates 391 and 392 forming the inner exterior of the drawer unit 32.

In detail, the drawer body 38 may be injection formed of a plastic material, and forms the overall shape of the drawer part 32. The drawer body 38 has a basket shape with an open top surface to form a food storage space therein. The rear surface of the drawer body 38 may be an inclined surface, so that interference with the machine room 3 may not occur.

The door frame 316 may be mounted on both sides of the drawer part 32. The door frame 316 may be coupled to the frame mounting portions 383 on both sides of the lower surface of the drawer unit 32 or the lower left and right sides of the drawer unit 32, and the door frame 316 is coupled to the drawer unit 32 The drawer part 32 and the door part 31 may be integrally coupled to be drawn in and out together.

The door frame 316 and the drawer unit 32 may be coupled to each other by a coupling structure by a separate coupling member or a fitting structure between the door frame 316 and the drawer unit 32.

The draw-out racks 34 may be provided on both left and right sides of the lower surface of the drawer part 32. Further, the draw-out rails 33 may be further provided on both left and right sides of the drawer part 32. Accordingly, the door 30 may be automatically pulled in and out, or if necessary, the user may push or pull the door 30 to pull in and out.

Further, the drawer body 38 may be provided with a plurality of plates 391 and 392 made of a plate-shaped metal material such as stainless steel to form at least a part of the interior and exterior of the drawer body 38.

In detail, outer side plates 391 may be provided on both left and right side surfaces outside the drawer body 38. The outer side plates 391 are mounted on both left and right sides of the drawer body 38 to form the exterior of both sides, and in particular, the door frame 316 and the draw-out rails mounted on both sides of the drawer body 38 ( 33) It can be prevented from being exposed to the outside.

Inner side plates 392 may be provided on both left and right sides of the drawer body 38 inside. The inner side plate 392 is mounted on both left and right side surfaces of the drawer body 38 and may form both left and right side surfaces of the drawer body 38.

The drawer part 32 may be provided with a drawer cover 37 that divides the inside of the drawer part 32 into a front space S1 and a rear space S2. The drawer cover 37 is bent at the upper end of the cover front part 371 and the cover front part 371 partitioning the inside of the drawer body 38 into a front space S1 and a rear space S2. , It may include a cover upper surface portion 372 shielding the upper surface of the rear space (S2).

That is, when the drawer cover 37 is mounted, only the front space S1 in which the lifting device 80 is disposed may be exposed inside the drawer body 38, and the rear space S2 is the drawer. It can be shielded by the cover 37.

In addition, the drawer cover 37 may be formed of a metal material such as the inner side plate 392 and the outer side plate 391. In addition, a front plate made of the same metal material may be further provided on the inner front surface of the drawer part 32. Therefore, the storage space inside the drawer 32 may have a metallic texture as a whole, and the food stored therein can be stored coldly in a more even area as a whole, as well as visually excellent cooling performance and storage for the user. Can provide performance.

Meanwhile, an elevating device 80 may be provided inside the drawer body 38. The lifting device 80 has a structure that is connected to the driving device 40 so as to be able to move up and down, and both left and right sides may be raised and lowered uniformly.

In order to couple the lifting device 80 and the driving device 40, drawer openings 35 are formed at both ends of the lower front side of the drawer part 32.

The drawer opening 35 is located at a position facing the cover opening 315a and may be formed in a shape corresponding to the cover opening 315a. That is, so as not to interfere with rotation of the scissor side connector 842 having a shape protruding from the rotation axis of the lifting device 80 to one side, the drawer opening 35 has a radius of the scissor side connector 842 It can be formed equal to or larger in size.

On the other hand, the lifting device 80 is configured as a scissor type, and is folded in a lowered state, and unfolded in an elevated state so that the container or food seated on the upper surface is raised and lowered.

In addition, the lifting device 80 may include a support plate 81, and the support plate 81 may provide a seating surface of the container 36 or a surface on which food is seated.

Meanwhile, the height of the drawer opening 35 may be located at a position lower than the upper end of the lifting device 80, that is, the upper surface of the support plate 81. Accordingly, in the state in which the lifting device 80 is mounted, it is possible to prevent the drawer opening 35 from being visible to the inside of the drawer part 32 in any state.

In addition, the support plate 81 has a size and shape corresponding to the front space to prevent foreign matters from penetrating into the lifting device 80 provided below the front space S1, and the lifting device 80 By blocking access to ), safety accidents can be fundamentally prevented.

13 is a perspective view of the lifting device. 14 is a front view of the upper frame of the lifting device in an elevated state. And, Figure 15 is a side view of the upper frame of the lifting device is raised. And, Figure 16 is an exploded perspective view of the lifting device.

As shown, the lifting device 80 may be mounted on the bottom of the inner surface of the drawer part 32 and may be detachably provided inside the drawer part 32.

In addition, the lifting device 80 may include an upper frame 82 and a lower frame 83, and a pair of scissors assembly 84 disposed between the upper frame 82 and the lower frame 83. have.

In detail, the upper frame 82 is formed in a rectangular frame shape corresponding to the size of the inner front space S1 of the drawer part 32, and the support plate 81 may be mounted on the upper surface.

The upper frame 82 is moved in the vertical direction of the lifting device 80 and substantially supports the food or container 36 together with the support plate 81.

The upper frame 82 may be formed in a plate shape of a metal material, and may be bent around to form a space for accommodating the scissor assembly 84 together with the lower frame 83.

In detail, the upper frame 82 is an upper plate portion 821 that forms an upper surface of the upper frame 82 as a whole, and extends downward along the circumference of the upper plate portion 821 to the upper frame 82 It may include an upper rim portion 822 forming the circumferential surface.

In addition, an upper supporting part 821a to which a plate roller 855 to be described below is in contact may be formed on the upper plate part 821. The upper supporting portion 821a may be formed to protrude downwardly by processing the upper plate portion 821 in the shape of a sheet metal or forming. In addition, when the lifting device 80 is operated, the plate roller 855 may extend along a moving path. The upper supporting portions 821a are respectively formed on the front and rear sides of each scissor assembly 84, and may be formed at positions corresponding to the pair of the scissors assembly 84, respectively. That is, as shown in FIG. 13, four of the upper supporting portions 821a may be provided in all of the upper plate portions 821.

In addition, a plate guide 824 for guiding the operation of the plate unit 85 may be provided on an inner surface, that is, a lower surface of the upper plate portion 821. The plate guide 824 may be formed to accommodate a plate slider 854 to be described below. The structure of the plate guide 824 and the coupling relationship with the plate slider 854 will be described in more detail below.

The lower frame 83 is provided below the upper frame 82 and may be seated on the bottom surface of the drawer part 32. The lower frame 83 may be formed in a shape corresponding to the upper frame 82.

The lower frame 83 may be formed in a plate shape of a metal material, and the circumference thereof may be bent to form an accommodation space for the scissors assembly 84 together with the upper frame 82.

In detail, the lower frame 83 has a lower plate portion 831 that forms a lower surface of the lower frame 83 as a whole, and extends downward along the circumference of the lower plate portion 831 so that the lower frame 83 It may include a lower rim portion 832 forming the circumferential surface of.

The lower edge portion 832 may be formed in a shape corresponding to the upper edge portion 822. Therefore, when the lifting device 80 is completely lowered to a state as shown in FIG. 13, the upper edge portion 822 and the lower edge portion 832 are close to each other to form a space therein, and the scissor assembly ( 84 may be completely accommodated in the space formed by the upper frame 82 and the lower frame 83.

The lower plate part 831 may be formed with a lower supporting part 831a to which the load roller 862 to be described below is in contact. The lower supporting part 831a may be formed to protrude downward by processing the plate-shaped lower plate part 831 by a processing such as sheet metal or forming. In addition, when the lifting device 80 is operated, it may be extended along a path along which the load roller 862 is moved. The lower supporting portions 831a are formed on the front and rear sides of each of the scissors assembly 84, and may be formed at positions corresponding to the pair of the scissors assembly 84, respectively. That is, as shown in FIG. 16, four lower supporting portions 831a may be provided in all of the lower plate portions 831.

Further, a rod guide 834 for guiding the operation of the load unit 86 may be provided on an inner surface, that is, an upper surface of the lower plate part 831. The rod guide 834 may be formed to accommodate a rod slider 861b, which will be described below. The structure of the rod guide 834 and the coupling relationship with the rod slider 861b will be described in more detail below.

In addition, a restraint device 89 may be provided in the center of the lower plate part 831. When the lifting device 80 is separated, the upper frame 82 and the lower frame 83 are not separated, and the restraint device 89 is constrained to each other so that the scissor assembly 84 is not unfolded. Keep it folded.

The restraint device 89 may include a restraint device case 891 fixed to the center of the lower frame 83, and a lower hook 862 that moves inside the restraint device case 891. In addition, an upper hook 88 may be provided at the center of the upper frame 82 corresponding to the lower hook 862.

The lower hook 862 is supported by a spring inside the restraining device case 891, and when the lifting device 80 is mounted on the drawer 32, the bottom surface of the drawer 32 The lower hook 862 is pushed while the protrusion of the lower frame 83 passes through the lower frame 83 to maintain a state away from the upper hook 88. And, the moment the lifting device 80 is separated from the drawer part 32, the lower hook 862 is elastically returned to the upper hook 88 direction by the spring, and the upper hook 88 and The lower hooks 862 may be constrained to each other so that the upper frame 82 and the lower frame 83 do not open, but may be constrained to each other.

Meanwhile, a scissor assembly 84 may be provided on both left and right sides of the upper frame 82 and the lower frame 83, respectively, based on the center of the upper frame 82 and the lower frame 83. The scissor assembly 84 is configured to be shaft-coupled and supported to the upper frame 82 and the lower frame 83, respectively. Accordingly, the upper frame 82 may be raised or lowered according to the operation of the scissor assembly 84.

The pair of scissors assembly 84 provided on both sides of the left and right only differs only in the mounting position, and the structure and shape are completely the same. Therefore, hereinafter, only one of the left and right sides of the scissors assembly 84 will be described.

The scissor assembly 84 may include a plate unit 85 and a rod unit 86 axially coupled to cross the plate unit 85. In addition, the plate unit 85 may be rotatably mounted on the lower frame 83.

In detail, in the lower frame 83, a first plate fixing member 873 and a second plate fixing member 874 so that the lower end of the plate unit 85 is rotatably mounted to the side end of the lower frame 83. ) May be provided. The first plate fixing member 873 is fixed to the lower frame 83, and the lower end of the plate unit 85 is rotated between the first plate fixing member and the second plate fixing member 874 coupled to each other. It can be combined as much as possible. Accordingly, the plate unit 85 may be rotated at the side end of the lower frame 83.

In addition, a first rod fixing member 871 and a second rod fixing member 872 may be provided in the upper frame 82. The first rod fixing member 871 and the second rod fixing member 872 may be coupled to each other to be axially coupled to an upper end of the rod unit 86. Accordingly, the load unit 86 may be rotatably mounted on the side end of the upper frame 82.

Meanwhile, hereinafter, the structure of the plate unit 85 will be described in more detail with reference to the drawings.

17 is a perspective view of a plate unit that is a configuration of the lifting device.

As shown in the drawing, the plate unit 85 may be formed in a rectangular plate shape. The plate unit 85 may be formed of an aluminum alloy material to have high strength and be lightly formed.

Further, the plate unit 85 may be formed by die casting, and not only can satisfy the strength required for the plate unit 85, but also the plate unit 85 having a complex shape can be molded at once.

The plate unit 85 is formed in a plate shape having a predetermined thickness, and reinforcing grooves 851 may be formed in the entire front and rear surfaces. The reinforcing groove 851 is recessed in a polygonal shape, and a plurality of the reinforcing grooves 851 may be disposed adjacent to each other on each side. Accordingly, a reinforcing groove 851 is disposed throughout the plate unit 85 to reinforce the strength of the plate unit 85.

Further, the reinforcing grooves 851 adjacent to each other may be disposed to be spaced apart from each other at the same interval. Accordingly, the rest of the reinforcing grooves 851 except for the reinforcing grooves 851, that is, between the reinforcing grooves 851 may have a structure such that ribs for reinforcement are formed. Accordingly, the plate unit 85 may have an uneven structure as a whole to reinforce the strength of the plate unit 85.

A scissor-side connection portion 842 may protrude from the lower end of the plate unit 85. The scissor side connection portion 842 is formed at an end portion of the extension portion 842b extending from the front end of the plate unit 85 and the extension portion 842b and formed in a shape corresponding to the lever side connection portion 422 It may include a coupling portion (842c).

Further, a plate hole 854 through which the second plate fixing member 874 passes may be formed at a lower end of the plate unit 85. The plate hole 854 may be formed one at the front and rear ends, and the plate unit 85 may be rotatably coupled to the lower frame 83 by the two second plate fixing members 874. have. Meanwhile, a rounded plate rotation shaft 854a may be formed at an end of the plate unit 85 corresponding to the plate hole 854, and may be a rotation center of the plate unit 85.

Side portions 852 may be formed at front and rear ends of the plate unit 85. The side portion 852 may form a front end and a rear end of the plate unit 85, and the scissor side connection portion 842 and the scissor slider 854 may protrude from the end of the side portion 852 . And, the reinforcing groove 851 may be configured not to be formed by being positioned outside the rod through hole 853.

Meanwhile, a rod through hole 853 penetrating the plate unit 85 may be formed in the first half and the second half of the central portion of the plate unit 85. The rod through hole 853 may be opened so that the first rod 861 and the second rod 861 ′ constituting the rod unit 86 pass through, respectively. In addition, a rod rotation shaft 852b protruding inward may be formed in the rod through hole 853. In addition, a screw hole 854b may be formed on an outer surface of the side portion 852 corresponding to the rod rotation shaft 852b.

That is, the first rod 861 and the second rod 861 ′ are inserted into the plate unit 85 to pass through the rod through hole 853, and the first rod 861 and the second rod ( 861') may be coupled to the rod rotation shaft 852b. In addition, a screw may be fastened to the screw hole 854b on the outer surface of the plate unit 85, and the screw passes through the rod rotation shaft 852b to pass through the first rod 861 and the second rod 861'. ) May be fastened to the rod fastening hole 861a.

Accordingly, the load unit 86 may be penetrated to cross the plate unit 85, and may be configured to rotate with respect to the plate unit 85 and the rod rotation shaft 852b.

Meanwhile, the rod through hole 853 may extend in the length direction of the plate unit 85 and may extend longer than cross-sections of the first rod 861 and the second rod 861 ′. . Therefore, even when the scissor assembly 84 is operated, the plate unit 85 and the rod unit 86 do not interfere, and the first rod 861 and the second rod are inside the rod through hole 853. Parts of (861') may be accommodated.

In addition, the rod through hole 853 is formed to be larger than the horizontal width of the first rod 861 and the first rod 861, and when the scissor assembly 84 is folded, the rod guide 834 Can be configured to be accommodated together.

That is, even if the scissor assembly 84 is folded, the first rod 861 and the second rod 861 ′ as well as the rod guide 834 are accommodated inside the rod through hole 853 Interference during operation of the scissor assembly 84 may be prevented, and the lifting device 80 may have a very compact thickness in a completely lowered state.

Meanwhile, plate sliders 854 protruding to both sides may be formed on the upper end of the plate unit 85. The plate slider 854 may extend to a predetermined length, and may be inserted into a space formed by the plate guide 824. In addition, when the scissor assembly 84 is operated, the plate slider 854 may move along the plate guide 824.

In addition, a plate roller 855 may be provided on the plate slider 854. The plate roller 855 is disposed so as to be in contact with the upper supporting part 821a, and may rotate the plate slider 854 about an axis. In addition, the plate slider 854 may pass through the plate roller 855 and further protrude outward.

Hereinafter, the structure of the load unit 86 will be described in more detail with reference to the drawings.

18 is a perspective view of a load unit that is a configuration of the lifting device

As shown, the load unit 86 is disposed between the first rod 861 and the second rod 861 ′ and the first rod 861 and the second rod 861 ′ disposed in the front and rear. It may include an upper connecting rod 863 and a lower connecting rod 866 to connect.

And, in a state in which the first rod 861 and the second rod 861', the upper connecting rod 863 and the lower connecting rod 866 are coupled, the rod unit 86 is formed in a rectangular frame shape. , It may have a structure that crosses through the plate unit 85.

On the other hand, the first rod 861 and the second rod 861 ′ differ only in their mounting positions, and may have the same size and structure. Therefore, hereinafter, only the configuration of the first rod 861 will be described in detail.

The first rod 861 may be formed in a rod shape that can pass through the rod through hole 853 and may have a length corresponding to the plate unit 85. In addition, a rod fastening hole 861a into which the rod rotation shaft 852b is inserted may be formed in the center of the first rod 861. Accordingly, the first rod 861 may be rotated about the rod rotation shaft 852b while being mounted to pass through the plate unit 85.

A load roller 862 may be provided at a lower end of the first rod 861. The load roller 862 is rotatably mounted at the lower end of the first rod 861 and may move while rotating along the lower supporting part 831a.

In addition, a rod slider 861b protruding inward may be provided at a lower end of the first rod 861. The rod slider 861b may extend along the lower connecting rod 866 and extend to be accommodated in the rod guide 834. Accordingly, when the rod unit 86 is rotated, the rod slider 861b may be guided by the rod guide 834.

Meanwhile, the rod slider 861b may be formed to protrude from the first rod 861 or may protrude from the lower connecting rod 866.

The lower ends of the first rod 861 and the second rod 861 ′ may be connected by the lower connecting rod 866. The lower ends of the first rod 861 and the second rod 861 ′ may be rigidly fixed by the lower connecting rod 866, and the rod unit 86 may maintain its shape.

In addition, upper ends of the first rod 861 and the second rod 861 ′ may be connected by the upper connecting rod 863. The upper ends of the first rod 861 and the second rod 861 ′ may be rigidly fixed by the upper connecting rod 863, and the shape of the rod unit 86 may be maintained.

In addition, upper sleeves 865 may be formed on both sides of the upper connecting rod 863. The upper sleeve 865 may have an outer surface formed in a cylindrical shape, and to be rotatably fixed to the upper frame 82 by the first rod fixing member 871 and the second rod fixing member 872. I can.

Hereinafter, the support structure of the plate unit 85 and the rod unit 86 and a structure for sliding guide will be described in detail with reference to the drawings.

FIG. 19 is a cut-away perspective view 19-19' of FIG. 13. And, Figure 20 is a perspective view showing a support structure of the plate unit of the lifting device. And, FIG. 21 is an enlarged view of part A of FIG. 20.

As shown in the drawing, rod guides 834 may be provided on both sides of the inner front part and the rear part of the lower frame 83. The rod guide 834 is disposed at the center of the lower frame 83, and ends of the rod unit 86 of a pair of scissors assemblies 84 positioned on both left and right sides may be accommodated together.

Guide extensions that are bent downward and coupled to the lower plate portion 831 may be formed at both side ends and the center of the rod guide 834. Accordingly, the rod guide 834 may be spaced apart from the lower plate portion 831 to form a space between the rod guide 834 and the bottom surface of the lower plate portion 831.

Further, a rod contact member 833 may be formed on an inner surface of the rod guide 834 along a longitudinal direction of the rod guide 834. The rod contact member 833 may be formed of a material having low frictional force, and smooth movement of the rod slider 861b and reduce noise and vibration.

In addition, the load roller 862 provided at the lower ends of the rods 861 and 861 ′ may be in contact with the lower supporting part 831a formed on the lower plate part 831. The lower supporting part 831a may be formed to have a narrower width as it protrudes upward, and thus, the load roller 862 and the lower supporting part 831a may be in line contact. By minimizing the contact area between the load roller 862 and the lower supporting part 831a, noise and vibration generated when the load unit 86 rotates may be minimized.

Meanwhile, the load roller 862 is supported from below by the lower supporting part 831a, and the rod slider 861b has a structure supported from above by the rod guide 834. That is, the lower end of the load unit 86 may have a structure that is supported in the vertical direction, and thus, when the load unit 86 is rotated, the flow in the vertical direction may be minimized to enable a stable operation.

22 is a perspective view showing the supporting structure of the plate unit of the lifting device. And, FIG. 23 is an enlarged view of part B of FIG. 22.

As shown, plate guides 824 may be provided on both sides of the inner first half and the second half of the upper frame 82. The plate guide 824 is disposed at the center of the upper frame 82, and ends of the plate unit 85 of the pair of scissors assemblies 84 positioned on both left and right sides may be accommodated together.

A guide extension portion that is bent downward and coupled to the upper plate portion 821 may be formed at both side ends and the center of the plate guide 824. Accordingly, the plate guide 824 may be spaced apart from the upper plate portion 821 to form a space between the plate guide 824 and the bottom surface of the upper plate portion 821.

Further, a plate contact member 823 may be formed on an inner surface of the plate guide 824 along the length direction of the plate guide 824. The plate contact member 823 may be formed of a material having low frictional force, and smooth movement of the plate slider 854 and reduce noise and vibration.

In addition, the plate roller 855 provided at the lower end of the plate unit 85 may be in contact with the upper supporting part 821a formed on the upper plate part 821. The upper supporting part 821a may be formed to have a narrower width as it protrudes downward, and thus, the plate roller 855 and the upper supporting part 821a may be in line contact. By minimizing the contact area between the plate roller 855 and the upper supporting part 821a, noise and vibration generated when the plate unit 85 rotates may be minimized.

Meanwhile, the plate roller 855 is supported from the upper side by the upper supporting part 821a, and the plate slider 854 has a structure supported by the plate guide 824 from below. That is, the upper end of the plate unit 85 may have a structure that is supported in the vertical direction, and thus, when the plate unit 85 is rotated, the flow in the vertical direction may be minimized to enable a stable operation.

Meanwhile, the scissor side connection part 842 may be provided on one side of the scissor assembly 84, and the scissor side connection part 842 may have a structure in which power is transmitted by being coupled with the lever side connection part 422. have.

24 is an enlarged view of a connection portion between the lifting device and the driving device.

As shown, the plate unit 85 may include a scissor side connecting portion 842 protruding to be connected to the lever 42. The scissor-side connection portion 842 is formed at an end portion of the extension portion 842b extending from the plate unit 85 and the extension portion 842b, and a coupling portion 842c having a shape corresponding to the receiving space 422c. ) Can be included.

The lever 42 may include a lever-side connecting portion 422 for receiving the scissor-side connecting portion 842 for coupling with the scissor-side connecting portion 842. The scissor side connection part 842 may be formed in a shape corresponding to the receiving space 422c inside the lever side connection part 422. That is, the scissor-side connection portion 842 may be formed in a shape extending from a circular axis of rotation to one side, and may be formed in a shape corresponding to the rotation portion 422b and the lever-side protrusion 422a.

The end of the scissor side connection part 842 may be formed in a non-circular shape. Therefore, when the lever 42 is rotated while the scissor side connection part 842 is accommodated in the lever side connection part 422, the lever 42 is prevented from spinning with the scissors side connection part 842 Can be. In addition, the scissor side connection part 842 can transmit a greater force for the operation of the lifting device 80.

Hereinafter, a state in which the door 30 of the refrigerator 1 according to an embodiment of the present invention having the above structure is pulled out and moved up and down will be described in more detail with reference to the drawings.

25 is a perspective view of the drawer door in a closed state.

Referring to FIG. 25, the refrigerator 1 maintains a state in which both the rotating door 20 and the door 30 are closed when food is stored. In this state, the user can store food by pulling out the door 30.

The door 30 may be provided with a plurality of upper and lower, and may be opened and extended by a user's manipulation.

At this time, the user's operation can be operated by touching the rotating door 20 or the operation unit 301 provided on the front of the door 30, and opening by the operation device 302 provided at the bottom of the door 30 Input of manipulation may be possible.

In addition, the operation unit 301 and the operation device 302 may be configured to individually operate the withdrawal of the door 30 and the lifting and lowering of the lifting device 80, respectively. Of course, it will also be possible for the user to hold the handle of the door 30 and open it.

And, hereinafter, the opening and elevation of the lower drawer door 30b among the doors 30 disposed in the upper and lower directions is described for example, but both the upper and lower doors 30 are withdrawn in the same manner. It will be able to be elevated.

26 is a perspective view of the drawer door fully open. And, Figure 27 is a cross-sectional view of the drawer door in a state in which the container of the drawer door is completely lowered. And, Figure 28 is a perspective view showing the state of the driving device and the lifting device in the state of Figure 27.

As shown, the lower drawer door 30b is pulled forward according to the user's pulling out operation of the lower drawer door 30b. The lower drawer door 30b may be pulled out while the pull-out rail 33 is extended.

On the other hand, the lower drawer door 30b may be configured not to be opened by pulling directly by a user, but to be withdrawn by driving the withdrawal motor 14.

The draw-out rack 34 provided on the bottom surface of the lower drawer door 30b may be coupled with a pinion gear 141 that is rotated when the draw-out motor 14 provided in the cabinet 10 is driven, and thus The lower drawer door 30b is pulled in and out as the pull-out motor 14 is driven.

The draw-out distance of the lower drawer door 30b may be extended to at least a distance at which the front space S1 inside the drawer part 32 can be completely exposed to the outside. Accordingly, in such a state, when the lifting device 80 is raised or lowered, the container or food does not interfere with the doors 20 and 30 or the cabinet 10 disposed above.

In this case, the draw-out distance of the lower drawer door 30b may be determined by the draw-out detection device 15 disposed on the cabinet 10 and/or the lower drawer door 30b.

The in/out detection device 15 may be configured as a detection sensor that detects a magnet 389 so that the lower drawer door 30b is completely pulled out or closed.

For example, as shown, a magnet 389 may be provided on the bottom of the drawer 32 and a detection sensor may be provided on the cabinet 10. The withdrawal detection device 15 corresponds to the position of the magnet 389 when the lower drawer door 30b is closed and the position of the magnet 389 when the lower drawer door 30b is completely withdrawn. It can be provided in a position. Accordingly, it is possible to determine the state of the drawing in and out of the lower drawer door 30b by the drawing in/out detecting device 15.

In addition, if necessary, a switch is provided at a position where the lower drawer door 30b is completely retracted and a position at which the lower drawer door 30b is completely retracted, so that the lower drawer door 30b may be sensed withdrawal and retracted, and the withdrawal motor 14 rotates. The number may be counted, or the withdrawal of the lower drawer door 30b may be detected by a sensor measuring a distance between the rear surface of the door 31 and the front end of the cabinet 10.

When the lower drawer door 30b is completely withdrawn, the driving motor 64 is driven to operate the lifting device 80. The elevating device 80 may be configured to be operated in a situation in which the lower drawer door 30b is sufficiently drawn out to ensure a safe elevating of the food or container 36 seated in the elevating device 80.

That is, when the lower drawer door 30b is pulled out and the front space S1 is completely exposed to the outside, the lifting device 80 is operated and the container 36 seated in the lifting device 80 or stored It is possible to prevent food from interfering with the other doors 20 and 30 or the cabinet 10.

Looking in more detail at the state in which the lower drawer door 30b is pulled out, when the lower drawer door 30b is pulled out for lifting, the front space S1 is completely outside the lower storage space 12. Must be withdrawn.

In particular, the rear end (L1) of the front space (S1) must be in a state that is more pulled out than the front end (L2) of the cabinet 10 or the upper door 20, and prevent interference when the lifting device 80 is elevated. In order to prevent it, it must be located in front of the cabinet 10 or the front end L2 of the upper door 20 at least.

In addition, when the lifting device 80 is pulled out to be driven, the entire drawer 32 is not completely pulled out, and as shown in FIG. 22, only to a position to avoid interference when the lifting device 80 is lifting. Can be withdrawn. At this time, at least a portion of the rear space S2 of the drawer 32 is located inside the lower storage space 12. That is, the rear end L3 of the drawer part 32 is positioned at least inside the lower storage space 12.

Therefore, even when the weight of the lower drawer door 30b including the driving device 40 and the lifting device 80 is added to the weight of the storage object, the draw-out rail 33 or the lower drawer door 30b ) It is possible to ensure stable withdrawal and lifting operation without sagging or damage of itself.

Before the lifting device 80 is raised, the lever 42 and the screw holder are located in the lowest position. The lifting detection device 90 detects this and determines that the current state is a state in which the lifting device 80 is completely lowered.

When it is determined that the lifting device 80 is in a completely lowered state by the lifting detection device 90, the driving device 40 starts operation when the user manipulates or completely withdraws the lower drawer door 30b. can do.

29 is a cross-sectional view of the drawer door when the container of the drawer door is completely raised. In addition, FIG. 30 is a perspective view showing states of the driving device and the lifting device in the state of FIG. 29.

As shown, in a state in which the lower drawer door 30b is withdrawn, when an operation signal of the driving device 40 is input, the driving device 40 is operated, and the elevation of the lifting device 80 Thus, the state as shown in FIG. 29 may be obtained.

In this embodiment, the lifting of the lifting device 80 means that the upper frame 82 is raised by the scissor assembly 84, and the descending of the lifting device 80 is caused by the scissor assembly 84. This means that the upper frame 82 is lowered.

The driving device 40 is in a state connected to the lifting device 80, and thus, power can be transmitted to the lifting device 80. With the start of the operation of the driving device 40, power is transmitted to the lifting device 80, and the lifting device 80 starts to ascend.

In detail, when the driving motor 64 rotates forward and backward by a rising or falling signal of the lifting device 80, the driving device 40 starts an operation.

Looking at the operation of the lifting device 80 ascending, the driving gear 651 rotates by the driving of the driving motor 64. The rotational force of the drive motor 64 is transmitted to the crossover gears 655 and 656 through the first to third transmission gears 652, 653 and 654 by the rotation of the drive gear 651.

The second helical gear portions 657 and 657a connected to the crossing gears 665 and 656 are rotated by the crossing gears 655 and 656 to change the power transmission direction. In addition, the screws 52 and 52a connected to the second helical gear units 657 and 657a are rotated.

At this time, since the same rotational force is transmitted to the screws 52 and 50a on both sides, the screw holders 56 and 56a are simultaneously raised by the same height.

As the screw holders 56 and 56a rise, the lever 42 connected to the screw holders 56 and 56a rotates. As the lever 42 connected to the screw holders 56 and 56a is rotated, the height of the lever 42 increases, and the plate connected to the lever 42 by increasing the height of the lever 42 The unit 85 is rotated together, and the upper ends of the plate unit 85 and the load unit 86 are raised.

When the plate unit 85 and the load unit 86 are rotated, the load roller 862 and the plate roller 855 are in contact with the lower supporting part 831a and the upper supporting part 821a, respectively. It will rotate. Further, the rod slider 861b and the plate slider 854 are moved along the rod guide 834 and the plate guide 824.

The scissor assembly 84 can be unfolded by the rotation of the plate unit 85 and the rod unit 86. As the scissor assembly 84 is unfolded, the upper frame 82 rises, and the container 36 or food seated on the support plate 81 rises, and finally, the lifting as shown in FIG. 29 The device 80 is raised to its maximum height.

On the other hand, the lifting device 80 is continuously raised and stops when it is raised to a sufficient height to facilitate access to the food or container 36 mounted on the lifting device 80 as shown in FIG. 29. In such a state, the user can easily lift the food or container 36 without excessively bowing the waist.

When the lifting device 80 is raised, the lever 42 and the screw holder are located at the highest positions, and the lifting detection device 90 detects this and the current state is determined by the lifting device 80 It is judged to be in a completely elevated state.

When it is determined by the lifting detection device 90 that the lifting device 80 is in a fully raised state, the driving motor 64 is stopped. In such a state, the lifting device 80 is located inside the drawer part 32, but the food or container 36 seated in the lifting device 80 is more than the opened upper surface of the drawer part 32. It can be located in a high position, allowing easy access by the user.

In particular, since it is not necessary to excessively bow the waist for lifting the container 36, a safer and more convenient operation is possible.

Looking in more detail at the state in which the lifting device 80 is raised to the maximum, the lifting device 80 is positioned at a lower position than at least the upper end of the drawer part 32.

When the container 36 is seated in the driving device 80 and viewed from the container 36, the upper end H1 of the container 36 is the upper end H2 of the lower storage space 12. ) Can be raised to a higher position. The height at this time is such that the user can reach out and lift the container 36 without bending the waist, and may be the most suitable height for use.

That is, the driving device 40 has a structure that is lifted from the inside of the drawer part 32, but the container 36 is in a state in which the container 36 is seated in the lifting device 80. It can be located at a height that is easily accessible.

On the other hand, in this state, the ends of the screw holder 56 and the lever 42 are in the highest state, and the state as shown in FIG. 30.

After the user's food storage operation is completed, the user may lower the lifting device 80 by operating the operation unit 301. The lowering of the lifting device 80 may be performed by reverse rotation of the driving motor 64, and may be gradually performed through a process opposite to the above-described process.

Then, when the lifting device 80 is lowered, it is in a state as shown in FIG. 27. At this time, the completion of the descending of the lifting device 80 is also performed by the lifting detection device 90. When the magnet is detected by the detection sensor 93 located below, the lifting device 80 determines that the descending has been completed, and the driving device 40 stops.

In addition, after the drive motor 64 is stopped, the lower drawer door 30b may be retracted. In this case, the lower drawer door 30b may be closed by a user's manipulation, or may be closed by driving the withdrawal motor 14. When the lower drawer door 30b is completely closed, the state as shown in FIG. 25 may be obtained.

Claims (20)

A cabinet in which a storage space is formed;
A door including a door portion for opening and closing the storage space by withdrawal and opening, and a drawer portion connected to the door portion and forming a storage space;
A rail connecting the door and the cabinet and for pulling out the door;
It is provided in the drawer portion, and includes a lifting device for lifting at least a portion of the drawer portion,
The lifting device,
A lower frame forming a bottom surface of the lifting device and fixed;
An upper frame spaced apart from the upper frame of the lower frame;
And a scissor assembly connecting the lower frame and the upper frame, and elevating the upper frame,
The scissor assembly,
A plate unit rotatably mounted on the lower frame and supporting the upper frame;
And a rod unit that includes a pair of rods intersected with the plate unit, is rotatably coupled to the upper frame, and supports the lower frame.
The method of claim 1,
The refrigerator, characterized in that the pair is provided on both sides of the scissor assembly.
The method of claim 1,
The elevating device is a refrigerator, characterized in that provided in the interior of the storage space.
The method of claim 3,
And a driving device connected to the lifting device to provide power for lifting the lifting device.
The method of claim 4,
A lever-side connection part is formed in the driving device,
The plate unit is provided with a scissor side connection,
And the scissor side connection part is connected to the driving device through the front surface of the drawer part.
The method of claim 5,
A drawer opening is formed in the front of the drawer corresponding to the lever-side connection part,
The scissor-side connection portion is detached from the lever-side connection portion through the drawer opening.
The method of claim 5,
Refrigerator, characterized in that the scissor-side connection part protrudes from the plate unit.
The method of claim 1,
The plate unit is a refrigerator, characterized in that formed of an aluminum alloy material.
The method of claim 1,
A refrigerator, characterized in that a polygonal reinforcing groove is continuously formed on the entire surface of the plate unit.
The method of claim 9,
Refrigerator, characterized in that the spaced between the plurality of adjacent reinforcing grooves at equal intervals.
The method of claim 1,
A refrigerator, wherein a rod through hole through which the load unit passes is formed in the plate unit.
The method of claim 11,
A refrigerator, characterized in that a rod rotation shaft to which the rod unit is rotatably coupled protrudes from the rod through hole.
The method of claim 11,
Rod sliders protruding laterally are formed at the lower ends of both sides of the load unit,
A refrigerator, characterized in that the lower frame is provided with a rod guide for accommodating the rod slider.
The method of claim 13,
The rod opening,
Refrigerator, characterized in that formed to have a width capable of accommodating the load unit and the rod guide at the same time when the scissor assembly is operated.
The method of claim 1,
Plate sliders protruding laterally are formed on upper ends of both side surfaces of the plate unit,
The refrigerator, characterized in that the upper frame is provided with a rod guide for accommodating the rod slider.
The method of claim 1,
Load rollers rotated in contact with the inner surface of the lower frame are provided at both lower ends of the load unit,
Refrigerator, characterized in that the plate rollers rotating in contact with the inner surface of the upper frame are provided at upper ends of both sides of the plate unit.
The method of claim 16,
The upper frame and the lower frame are formed in a plate shape,
A lower supporting portion protruding along a moving path of the load roller and in line contact with the load roller;
And an upper supporting portion protruding along a moving path of the plate roller and in line contact with the plate roller.
The method of claim 1,
The upper frame and the lower frame are formed in a plate shape and are bent around to accommodate the scissor assembly in a state in which the upper frame is lowered.
The method of claim 1,
The load unit,
A first rod and a second rod passing through both sides of the plate unit;
And an upper connecting rod and a lower connecting rod connecting upper and lower ends of the first rod and the second rod.
The method of claim 19,
A pair of rod through holes opening in the extending direction of the first rod and the second rod are formed on both sides of the plate unit so as not to interfere with the first rod and the second rod during operation of the scissor assembly,
The first rod and the second rod are axially coupled inside the pair of rod through holes.

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