KR102304984B1 - drawer and refrigerator with drawer - Google Patents

Abstract

The present invention relates to a refrigerator provided with a drawer device and a drawer window device so that at least a part of the inside of a drawer to be drawn in and out can be automatically moved up and down by a user's manipulation.

Description

Refrigerator equipped with drawer device and drawer device { drawer and refrigerator with drawer }

The present invention relates to a drawer device and a refrigerator equipped with a drawer device.

BACKGROUND ART In general, a refrigerator is a home appliance that allows food to be stored at a low temperature in an internal storage space that is shielded by a door. It is designed to store food in an optimal state.

Such refrigerators are becoming larger and more multifunctional in accordance with changes in eating habits and diversification of user preferences, and refrigerators equipped with various structures and convenience devices for user convenience and freshness of stored food are being released.

In general, a drawer provided to be able to be drawn in and out may be provided in the interior space. In the drawer, food that needs to be stored separately, such as vegetables and fruits, may be stored, and the inside of the drawer may be opened and closed by a user's pulling-in/out operation.

When the drawer is provided at the lower end of the storage space, the user must squat down or bow down to store food in the drawer, and there is a problem in that it is not easy to operate the drawer.

For the convenience of users, Korean Patent Laid-Open No. 10-2009-003332 discloses a refrigerator to which a drawer structure that can be automatically drawn in and out is applied. And, Korean Patent Laid-Open Publication No. 10-2004-0093111 discloses a refrigerator to which a drawer structure capable of automatically lifting and lowering is applied.

However, such conventional techniques have a problem that the withdrawal and elevating structures are configured separately, so that inconvenience in use still exists.

It is an object of the present invention to provide a drawer device capable of automatically taking out and raising and lowering a drawer, and a refrigerator provided with the drawer device.

It is an object of the present invention to provide a drawer device and a refrigerator equipped with a drawer device that can automatically take out and lift a drawer by one operation.

It is an object of the present invention to provide a refrigerator equipped with a drawer device and a drawer window device so that at least a portion of the inside of a drawer to be drawn in and out can be automatically moved up and down by a user's manipulation.

A drawer device according to an embodiment of the present invention comprises: an external storage unit that forms a space with an open upper surface, and is drawn out and inserted into an inner side of a cabinet; a pull-out guide provided on the outside of the external accommodating part and for guiding the pull-out and entry of the external accommodating part; an inner accommodating part which forms at least a part of a bottom surface of the accommodating space in the interior of the external accommodating part and is raised and lowered; and a drive assembly coupled to the pull-out guide and the inner accommodating part, the driving assembly providing power for pulling-out and elevating the external accommodating part, wherein the drive assembly provides power to the pull-out guide In a state in which the mouth guide is drawn out, it is characterized in that the inner accommodation unit is raised and lowered.

The inner accommodating part is formed in a plate shape, and it is possible to form the bottom of the accommodating space.

The inner accommodating part may be formed in a basket shape with an open upper surface.

It is possible that an elevating guide for guiding the vertical movement of the inner accommodating part is formed in the outer drawer.

The pull-out guide may be provided on an inner surface of the cabinet, and the drive assembly may be provided on an external receiving unit.

The driving assembly may include a motor; a drive shaft rotated by the motor; a pinion connected to the drive shaft and rotated together with the drive shaft, the pinion being moved along the pull-out guide; a clutch provided on the drive shaft to selectively transmit the rotational force of the motor to the pinion; and a wire that connects the clutch and the internal accommodating part, and is wound around the clutch in a state in which power transmission to the pinion is blocked, and elevates the internal accommodating part.

The drive shaft may include a first drive shaft connected to the rotation shaft of the motor; and a second drive shaft spaced apart from the first drive shaft on the same extension line and connected to the pinion, wherein the clutch selectively connects the first drive shaft and the second drive shaft to the second drive shaft. It is possible to transmit rotational power.

The first drive shaft includes a first screw thread inserted into and coupled to a screw coupling part inside the clutch, and the second drive shaft is inserted into the clutch at an end of the second drive shaft and is not engaged with the clutch. a non-coupled part; and a second thread formed toward the pinion at an end of the uncoupled part and coupled to the threaded part, wherein the clutch transmits power to the pinion when engaged with the second thread; In a state in which the first driving side is completely moved, a non-coupled portion is inserted inside the clutch to block power transmission to the pinion.

The first drive shaft includes a first screw thread inserted into and coupled to a screw coupling part inside the clutch, and the second drive shaft is inserted into the clutch at an end of the second drive shaft and is not engaged with the clutch. a rotating part and a connecting part extending from an end of the rotating part toward the pinion and having a polygonal cross-sectional shape having the same shape as an opening of the clutch end, wherein the clutch transmits power to the pinion in a state coupled to the connecting part And, in a state in which the clutch is completely moved to the first driving side, a rotating part is inserted into the clutch to block power transmission to the pinion.

The first drive shaft may include a first screw thread inserted into and coupled to a screw coupling part inside the clutch; It is provided on the first drive shaft and includes a restraining member that is moved according to the movement of the clutch, and the second drive shaft includes a restraint that is selectively restrained and coupled to the restraining member according to the movement of the restraining member, the clutch transmits power to the pinion when the restraining member is constrained to the restraining part, and the clutch is moved to contact the restraining member so that the power to the pinion in a state in which the restraining member is released from the restraining part It is possible to block transmission.

The driving assembly may include a motor; a motor gear rotated by the shaft of the motor; a drive shaft extending parallel to the axis of the motor; a driving gear provided on the driving shaft and selectively connected to the motor gear to transmit power to the driving shaft; a pinion provided on the drive shaft and rotated together with the drive shaft, the pinion being moved along the pull-out guide; a clutch disposed slidably along the drive shaft and selectively transmitting the rotational force of the motor to the pinion; and a stopper formed of a metal material on one side of the clutch and moving the clutch by a magnet provided in the pull-out guide.

The motor gear includes a first motor gear and a second motor gear spaced apart from each other on the shaft of the motor, and the driving gear is spaced apart from the driving shaft, the first driving gear being rotated together with the pinion and the and a second drive gear rotated together with the clutch, wherein the first motor gear is coupled to the first drive gear according to the movement of the clutch, and the second motor gear is coupled to the second drive gear. .

The drive shaft has a polygonal cross-sectional shape, the first drive gear is mounted thereon and the first drive part rotates the drive shaft together by the driving force of the motor, and has a circular cross-sectional shape, and the second drive gear and the clutch are It is possible to include a second drive that allows it to be rotated independently of the drive shaft.

The magnet may be provided at one point of the pull-out guide corresponding to the position of the clutch in a state in which the external receiving part is completely withdrawn.

The magnet is an electromagnet, and it is possible to generate magnetic force by applying power in a state in which the external accommodating part is drawn out, and to dissipate the magnetic force by cutting off the power in a state where the lowering of the internal accommodating part is completed.

The stopper may be provided with an elastic member for elastically supporting the gear motor and the driving motor to return to their original coupling positions.

A refrigerator equipped with a drawer device according to an embodiment of the present invention includes: a cabinet in which a storage space is formed; and a drawer device provided in the storage space, wherein the drawer device includes: an external storage unit that is provided to be withdrawn and inserted inside the storage space and forms a space with an open upper surface; a pull-out guide provided on the outside of the external accommodating part and for guiding the pull-out and entry of the external accommodating part; an inner accommodating part which forms at least a part of a bottom surface of the accommodating space in the interior of the external accommodating part and is raised and lowered; and a drive assembly coupled to the pull-out guide and the inner accommodating part, the driving assembly providing power for pulling-out and elevating the external accommodating part, wherein the drive assembly provides power to the pull-out guide It is possible to elevate the inner accommodating part in a state in which the mouth guide is drawn out.

The cabinet may include a door that opens and closes the storage space and is coupled to the external storage unit to be drawn in and out together.

A door that opens and closes the storage space by rotation and shields the external accommodating part is mounted on the opened front surface of the cabinet, and the door can be opened and closed independently of the take-out and entry of the external accommodating part.

The pull-out guide may be provided on both side wall surfaces of the storage space, and the drive assembly may be provided in the external receiving unit.

The pull-out guide may be provided on both sides of the external receiving unit, and the drive assembly may be provided on both side wall surfaces of the storage space.

The drawer device and the refrigerator equipped with the drawer device according to an embodiment of the present invention can expect the following effects.

The drawer device according to an embodiment of the present invention is configured so that a portion of the drawer device can be lifted and lowered after being pulled out by a user's operation. Therefore, when the drawer device is disposed in the lower portion, there is an advantage that the user does not need to excessively bend the waist or apply excessive force to lift the stored object when food is stored in the drawer device, so that the convenience of use can be dramatically improved. .

In particular, the drawer device can be lifted after being drawn out to the outside through one operation, and can be retracted after being lowered through another operation, thereby maximizing the convenience of use.

In addition, in the drawer device, the external storage member is configured to be pulled out and the inner storage member is configured to be raised and lowered, so that the food inside the drawer device can be pulled out and moved in and out without the entire storage device being pulled out and moved up and down. And it is possible to simplify the configuration for lifting and lowering, there is an advantage that can secure the safety in use.

In addition, the drive assembly for drawing-in and lowering of the drawer device may have a simple configuration, and in particular, both drawing-out and elevating of the drawer device are possible through one drive assembly, thereby reducing manufacturing cost and improving productivity. can be expected

In addition, there is an advantage in that the loss of the storage space of the storage device can be minimized due to the simple configuration of the driving assembly.

In addition, power may be provided to the drive assembly through a single motor, and power may be selectively transmitted to the pinion through a clutch, and at the same time, lifting and lowering of the internal housing member is also possible, thereby simplifying the configuration of the drive assembly. There are advantages that can be

In addition, the clutch enables the internal storage unit to be raised and lowered after the withdrawal of the storage member is completed by selective switching of the power connection, so that sequential operations can be implemented with a simple structure, which is generated during lifting or withdrawing There is an advantage in that safety accidents or malfunctions can be prevented.

1 is a front view of a refrigerator according to a first embodiment of the present invention.
2 is a view showing a state in which the door of the refrigerator is opened.
3 is a view showing a state in which the drawer device according to the first embodiment of the present invention is withdrawn.
4 is a view showing a state in which a part of the drawer device is lifted.
5 is an exploded perspective view of the drawer device.
6 is an exploded perspective view showing the coupling structure of the clutch of the main configuration of the drawer device.
7 is a view sequentially illustrating the operation of the clutch.
8 is a cross-sectional view showing a state in which the drawer device is retracted.
9 is a cross-sectional view showing a state in which the drawer device is drawn out.
10 is a cross-sectional view showing a state in which a part of the drawer device is raised.
11 is a perspective view showing the structure of a drawer device and a drive assembly according to another second embodiment of the present invention.
12 is a cutaway perspective view showing the structure of a drawer device and a drive assembly according to another third embodiment of the present invention.
13 is an exploded view showing the coupling structure of the driving assembly according to the fourth embodiment of the present invention.
14 is a view sequentially illustrating the operation of the clutch of the drive assembly.
15 is an exploded view showing the coupling structure of the driving assembly according to the fifth embodiment of the present invention.
16 is a view sequentially illustrating the operation of the clutch of the drive assembly.
17 is a view showing the configuration of a driving assembly according to a sixth embodiment of the present invention.
18 to 21 are views sequentially illustrating the operation of the clutch of the drive assembly.
23 is a front view of a refrigerator according to a seventh embodiment of the present invention.
24 is a view showing an open door of the refrigerator.
25 is a view showing a state in which the storage member of the refrigerator is withdrawn.
26 is a cross-sectional view of the storage member drawn out from the side.

Hereinafter, specific embodiments of the present invention will be described in detail with drawings. However, it cannot be said that the spirit of the present invention is limited to the presented embodiment, and other degenerative inventions or other embodiments included within the scope of the spirit of the present invention can be easily made by addition, change, deletion, etc. of other components. can suggest

In the embodiment of the present invention, for convenience of explanation and understanding, a bottom freezer-type refrigerator in which a freezing compartment is provided below a refrigerating compartment is described as an example, but the present invention is not limited thereto, and all items that can be provided in and out of the refrigerator are not limited thereto. It should be clarified in advance that it can be applied to a type of drawer device and a refrigerator equipped with a drawer device.

1 is a front view of a refrigerator according to a first embodiment of the present invention. And, FIG. 2 is a view showing a state in which the door of the refrigerator is opened.

The refrigerator 1 according to an embodiment of the present invention may have an external shape formed by a cabinet 10 forming a storage space and a door opening and closing the storage space.

The interior of the cabinet 10 may be partitioned up and down by a barrier 11 , a refrigerating compartment 12 may be formed at an upper portion of the cabinet 10 , and a freezing compartment 13 may be formed at a lower portion of the cabinet 10 . can be formed. In addition, various accommodating members such as shelves, drawers or baskets may be provided inside the refrigerating compartment 12 and the freezing compartment 13 . The refrigerating compartment 12 and the freezing compartment 13 may be referred to as an upper storage space or a lower storage space.

The door may include a refrigerator compartment door 20 and a freezer compartment door 30 . The refrigerating compartment door 20 opens and closes the opened front of the refrigerating compartment 12 by rotating, and the freezing compartment door 30 is configured to open and close the opened front of the refrigerating compartment 13 by sliding pull-out. have. In addition, the refrigerating compartment door 20 may be referred to as an upper door and the freezing compartment door 30 may be referred to as a lower door.

The refrigerating compartment door 20 may be configured as a pair, and each of the refrigerating compartment doors 20 may open and close the opened front portion of the refrigerating compartment 12 by rotation. In addition, a dispenser 21 for dispensing water or ice may be provided on the front side of the refrigerator compartment door 20 on one side (left side in FIG. 1 ). In addition, an ice-making chamber 22 provided with an ice maker may be formed on the rear surface of the refrigerator compartment door 20 provided with the dispenser 21 . The living ice making chamber 22 may form an insulating space independent from the refrigerating chamber 12 and may have an openable and openable structure.

A display 23 for displaying the operating state of the refrigerator 1 may be provided on one side of the dispenser 21 . In addition, a manipulation unit 231 for controlling the operation of the refrigerator 1 may be provided on one side of the display 23 . The manipulation unit 231 may be spherical in a button method or a touch method.

The refrigerating compartment door 20 on the other side (the right side in FIG. 1 ) of the refrigerating compartment door 20 may have a see-through part 24 through which the space behind the refrigerating compartment 12 can be seen through. According to a user's manipulation, the see-through unit 24 may be selectively made transparent or opaque, and may be configured to enable display of information and touch input if necessary. The refrigerating compartment door 20 opens and closes the refrigerating compartment 12, a main door 201 having an auxiliary storage space formed in a central opening, and opens and closes an opening of the main door 201, and the see-through part 24 It may be composed of a sub-door 202 formed. The main door 201 and the sub-door 202 may be configured to be rotatable in the same direction.

The freezing compartment door 30 may be provided on the front side of the freezing compartment 13 , and may be configured to be integrally drawn in and out with the storage member 31 provided on the rear surface of the freezing compartment door 30 . The entire configuration, including the freezer compartment door 30 and the storage member 31, to be drawn in and out may be referred to as a drawer device. Of course, the drawer device may be separated from the freezing compartment door 30 to refer to only the storage member 31 .

An upper basket 131 may be provided at an inner upper end of the freezing compartment 13 . The upper basket 131 is also configured to be able to be drawn in and out in the front and rear directions, and can be drawn in and out independently after the freezing compartment door 30 is opened.

3 is a view showing a state in which the drawer device according to the first embodiment of the present invention is withdrawn. And, Figure 4 is a view showing a state that a part of the drawer device is lifted.

As shown in the drawing, the drawer device may include the freezing compartment door 30 and a storage member 31 provided on the rear surface of the freezing compartment door 30 .

The front surface of the freezing compartment door 30 may form a front exterior of the refrigerator 1 in a state in which the freezing compartment door 30 is closed, and may be formed of a metal material. In addition, a handle 32 for opening and closing the freezing compartment door 30 may be provided at the upper front end of the freezing compartment door 30 .

In addition, the handle 32 may further include a handle operation unit 321 for automatically withdrawing and/or lifting the freezer door 30 . The handle manipulation unit 321 may be configured as a button type for a user's manipulation input, and may include a sensor for sensing a user's touch or manipulation.

The accommodating member 31 may be formed in a basket shape with an open upper surface, and may be fixedly mounted to a frame provided on the rear surface of the freezing compartment door 30 . Although not shown in detail, the frame may be formed in a rectangular frame shape and disposed around the accommodating member 31 , and the accommodating member 31 may be detachably attached to the frame.

In addition, the drawer device can be pulled out and lifted by the manipulation of the manipulation unit 231 or the handle manipulation unit 321 . The drawing-out and elevating operation of the drawer device may be independently performed as one operation of drawing-out, raising, and lowering according to the operation form of the manipulation unit 231 or the handle manipulation unit 321, and may be performed as a single operation. At least one operation of withdrawing, ascending, descending, and withdrawing may be continuously performed.

In addition, rails 33 may be provided on both sides of the accommodating member 31 . The rail 33 is for pulling out the freezer compartment door 30 and the accommodating member 31 that are drawn out to the outside, and may be composed of a metal rail drawn out in multiple stages.

Drawer guides 132 to which the rails 33 are fixed may be formed on both inner side surfaces of the freezing compartment 13 . One end of the rail 33 may be fixedly mounted to the drawer guide 132 , and the rail 33 extends in multiple stages so that the entire or most of the housing member 31 is outside the freezing compartment 13 . to allow it to be withdrawn.

In addition, the drawer guide 132 may extend long in the direction in which the drawer device is drawn out, and a rack part 133 for automatic drawing out of the storage member 31 may be formed. The rack part 133 may be formed along the drawer guide 132 in the same structure as a rack gear. Of course, the drawer guide 132 and the rack part 133 may be formed as separate components, and may be disposed on both left and right sides of the inside of the freezing compartment, respectively. In addition, the rack part 133 may guide the withdrawal and entry of the receiving member 31 in a structure other than the coupling structure with the pinion 42 , so the rack part 133 is called a withdrawal guide. can

The accommodating member 31 may be provided with a driving assembly 40 including a motor 41 and a pinion 42 . The driving assembly 40 may be driven by an input signal of the manipulation unit 231 or the handle manipulation unit 321 , and the receiving member 31 is pulled out and the receiving member 31 , and an internal receiving unit inside the receiving member 31 . (34) may be configured to be able to elevate.

That is, the drawer device may be composed of an external accommodating part and an internal accommodating part 34 coupled to the freezing compartment door 30, and the external accommodating part is drawn out in the front-rear direction, and the internal accommodating part 34 is moved up and down. It may be configured to be lifted. The drawing-in/out of the external accommodating part and the raising/lowering of the internal accommodating part 34 may be continuously performed by the driving assembly 40 .

The driving assembly 40 may be provided on the rear surface of the housing member 31 , and the pinion 42 may be rotated by the rotation of the motor 41 . The pinion 42 may be disposed on both left and right sides of the accommodating member 31 , and may be gear-coupled to the rack part 133 . Therefore, the pinion 42 can be rotated by the driving of the motor 41, and the drawer device, that is, the storage member 31 and the freezer compartment door 30, are rotated according to the forward and reverse rotation of the motor 41. It can be automatically drawn in and out in the front and rear directions.

The drawer device can be withdrawn as shown in FIG. 3 by the driving of the driving assembly 40, and after the drawer device is pulled out, the inner receiving part 34 including the bottom surface of the inside of the receiving member 31. may be raised to a state as shown in FIG. 4 . That is, in the state in which the inner accommodating part 34 is raised as shown in FIG. 4 , it is possible for the user to take out the food stored in the internal accommodating part 34 without bending the waist much.

The internal accommodating part 34 is provided inside the accommodating member 31 and may include at least a portion of an inner bottom surface of the accommodating member 31. The internal accommodating part 34 may be formed in a plate shape. have. In addition, the inner accommodating part 34 may extend upward in addition to the inner bottom surface of the accommodating member 31 to form at least a portion of the inner circumferential surface.

On the other hand, the lifting guides 311 for guiding the vertical movement of the accommodation member 31 may be formed on the left and right side surfaces of the accommodation member 31 . The elevating guide 311 may be opened in a vertical direction, and a portion of the inner accommodating part 34 may be penetrated to move up and down along the elevating guide 311 . And, although not shown in detail, the inner side of the elevating guide 311 may be shielded so that foreign substances are not introduced when the inner accommodating part 34 is elevating.

Hereinafter, the drawer device will be described in more detail with reference to the drawings.

5 is an exploded perspective view of the drawer device.

As shown in the drawing, the drawer device may include the accommodating member 31 and a driving assembly 40 mounted to the accommodating member 31 .

The inner accommodating part 34 may be accommodated in the accommodating member 31 . The inner accommodating part 34 may be guided upward and downward by the circumferential surface of the accommodating member 31 , and may be lifted in a state in which the food accommodated in the accommodating member 31 is seated.

The internal accommodating part 34 may be formed in a plate shape to form a part of the bottom surface of the accommodating member 31 , wherein the width of the internal accommodating part 34 corresponds to the inner width of the accommodating member 31 . can be formed to In addition, the inner accommodating part 34 may be formed in a basket shape accommodated on the inner surface of the accommodating member 31 .

A receiving unit frame 341 may be further provided on a lower surface of the inner receiving unit 34 . The accommodating part frame 341 may be formed of a metal material, and may be coupled to a lower surface of the internal accommodating part 34 to support the internal accommodating part 34 .

The accommodating part frame 341 is formed in a rectangular frame shape, and is formed smaller than the size of the inner accommodating part 34 so that it is not exposed to the outside when viewed from above and does not interfere with the lifting and lowering of the internal accommodating part 34. It can be configured not to. The accommodating part frame 341 is formed along the periphery of the lower surface of the inner accommodating part 34 to provide stable support when the internal accommodating part 34 is raised and lowered. In this state, the internal housing 34 is prevented from being deformed or damaged.

Frame coupling parts 342 may be formed on both sides of the receiving part frame 341 . The frame coupling portion 342 may be formed at a position corresponding to the elevating guide 311 , and may be formed to pass through the elevating guide 311 . In addition, a lower pulley 462 to be described below may be rotatably coupled to the frame coupling part 342 . The lower pulley 462 may be disposed on the outer surface of the accommodating member 31 and elevate the accommodating part frame 341 by a wire 43 to be described below.

On the other hand, the accommodating part frame 341 may be formed of a metal material having excellent strength, unlike the internal accommodating part made of a plastic material, and may have a structure coupled to the internal accommodating part 34 . And, if necessary, if the housing frame 341 has a stable support structure, it may be integrally formed when the inner housing 34 is formed.

At least a portion of the driving assembly 40 may be disposed on both sides of the receiving member 31 , and a receiving member cover 312 for shielding the driving assembly 40 disposed on both sides of the receiving member 31 is provided. can be provided. The accommodating member cover 312 may form at least a portion of the exterior of both sides of the accommodating member 31 , and provide a space in which at least a portion of the driving assembly 40 can be accommodated. In addition, in the state in which the housing member cover 312 is mounted, components mounted on both sides of the housing member 31 among the driving assembly 40 may be shielded so that they are not exposed to the outside.

In addition, the motor 41, the clutch 44, and the pinion 42 may be provided on the rear surface of the accommodating member 31 . The motor 41 may be fixedly mounted to the housing member 31 , and the driving shaft 45 rotated by the motor 41 may extend outward. The driving shaft 45 may include a first driving shaft 451 connected to the motor 41 and a second driving shaft 452 connected to the pinion 42 . The first driving shaft 451 and the second driving shaft 452 may be disposed on the same extension line, and may be spaced apart so that their ends face each other.

In addition, a clutch 44 connecting between the first drive shaft 451 and the second drive shaft 452 may be provided. The clutch 44 is configured to selectively connect the first drive shaft 451 and the second drive shaft 452 to transmit power when the motor 41 is operated. That is, according to the operation of the clutch 44 , the first drive shaft 451 and the second drive shaft 452 may be connected to enable power transmission, and in this case, the first drive shaft 451 and the second drive shaft 452 . ) can be rotated together.

Also, the clutch 44 may be in a state in which power is not transmitted between the first drive shaft 451 and the second drive shaft 452 . When the first drive shaft 451 and the second drive shaft 452 rotate independently of each other by the clutch 44, only the first drive shaft 451 can be rotated when the motor 41 is driven. have. The configuration and operation of the clutch 44 will be described in more detail below.

The first driving shaft 451 is mounted on the motor 41 , and the second driving shaft 452 is coupled to the pinion 42 in a state away from the first driving shaft 451 . In addition, the clutch 44 is disposed between the first drive shaft 451 and the second drive shaft 452 , and the clutch 44 moves along the first drive shaft 451 and the second drive shaft 452 . can be moved

The second driving shaft 452 may be connected to the center of the pinion 42 , and when the second driving shaft 452 rotates, the pinion 42 may be rotated. That is, when the motor 41 rotates in a state in which the first drive shaft 451 and the second drive shaft 452 are connected by the clutch 44 , the pinion 42 may be rotated. The pinion 42 is gear-coupled to the rack part 133 and moves along the rack part 133 . And, if necessary, the motor 41, the first drive shaft 451, the second drive shaft 452, the clutch 44, and the pinion 42 may have a structure that is shielded by a separate cover.

The wire 43 may be connected to the clutch 44 . The wire 43 may be formed of a resin or metal material, and may include a plurality of connection structures such as chains. The wire 43 may be formed in a band shape connecting the clutch 44 and the pulley 46 , and various other configurations that may be wound around the clutch 44 may be possible. In addition, the wire 43, the clutch 44, and the pulley 46 may have various connection methods.

The pulley 46 may include a lower pulley 462 coupled to the housing frame 341 and an upper pulley 461 disposed between the lower pulley 462 and the clutch 44 . . The wire 43 may be configured to connect the clutch 44 and the upper pulley 461 and the lower pulley 462 . The upper pulley 461 and the lower pulley 462 may be rotatably coupled, and the wire 43 may be configured to pass therethrough.

On the other hand, the lower pulley 462 may be rotatably coupled to the frame coupling part 342 to facilitate lifting and lowering of the inner accommodation part 34 . In addition, the upper pulley 461 may be rotatably mounted on the outer surface of the accommodating member 31 . In this case, the upper pulley 461 may be positioned vertically above the lower pulley 462 , and may be positioned at the same height as the clutch 44 . Accordingly, the wire 43 can be connected from the clutch 44 to the lower pulley 462 via the upper pulley 461 , and is wound by the clutch 44 to the inner receiving part 34 . can be lifted upwards. Of course, in addition to the upper pulley 461 and the lower pulley 462, in addition to the upper pulley 461 and the lower pulley 462, a configuration that functions as an additional pulley or a pulley may be further provided to enable the inner accommodation part 34 to be raised and lowered by the wire 43. Also, the positions of the upper pulley 461 and the lower pulley 462 may be variously changed.

In a state in which the upper pulley 461, the lower pulley 462, and the wire 43 are disposed, the housing member cover 312 may be mounted to the housing member 31, and the upper pulley 461 and the lower portion The pulley 462 and the wire 43 may be shielded so as not to be exposed to the outside.

6 is an exploded perspective view showing the coupling structure of the clutch of the main configuration of the drawer device.

The illustrated driving assembly 40 shows only the components disposed on one side of the left and right sides of the receiving member 31, only the arrangement direction is symmetrical, and the coupling structure and operation are the same. do it with

As shown, the motor 41, the first drive shaft 451, the clutch 44, the second drive shaft 452, and the pinion 42 constituting the drive assembly 40 are continuously arranged on the same extension line. can be Through such an arrangement, the drawer device can be automatically drawn in and out according to the operation of the driving assembly 40 , and the internal accommodating part 34 of the drawer device can be raised and lowered.

The motor 41 may be fixedly mounted to the housing member 31 , and the first driving shaft 451 coupled to the motor 41 faces the drawer guide 132 on which the rack part 133 is formed. is extended A first screw portion 451a coupled to a screw coupling portion inside the clutch 44 may be formed on the first drive shaft 451 . The first screw portion 451a may be formed to be coupled to the screw coupling portion 442 .

Also, according to the rotation of the first driving shaft 451 , the clutch 44 may move along the first driving shaft 451 . Depending on the rotational direction of the motor 41 , the clutch 44 may move toward the motor 41 or toward the pinion 42 .

A second drive shaft 452 may be connected to the other side of the clutch 44 . The second drive shaft 452 may extend from the clutch 44 to the rack part 133 , and the pinion 42 may be mounted at an end of the second drive shaft 452 . In addition, the pinion 42 may have an outer peripheral surface formed in a gear shape corresponding to the rack part 133 so as to be coupled to the rack part 133 .

In addition, the second driving shaft 452 may be formed to have the same outer diameter as the first driving shaft 451 , and a second screw portion 452a may be formed on an outer circumferential surface of the second driving shaft 452 . The second screw portion 452a may have a shape corresponding to the screw coupling portion 442 of the clutch 44 . Accordingly, the clutch 44 becomes possible to move along the second drive shaft 452 through engagement with the second screw portion 452a.

The second drive shaft 452 is inserted into the hollow of the clutch 44 in a state in which the clutch 44 is moved closest to the motor 41 side, but is not coupled to the screw coupling part 442 . Thus, it is possible to prevent the rotational force of the motor 41 from being transmitted to the second driving shaft 452 . To this end, an uncoupled portion 452b in which the second screw portion 452a is not formed may be formed in the second drive shaft 452 from the end extending toward the clutch 44 to the end of the clutch 44 . . In addition, the second screw portion 452a may be formed from the non-coupled portion 452b to the pinion 42 . That is, when the screw-coupled portion 442 of the clutch 44 passes the second screw portion 452a and is positioned at the non-coupled portion 452b, the second drive shaft 452 is coupled with the clutch 44. will not rotate.

The clutch 44 is formed in a cylindrical shape with hollows 441 passing through both ends, and the first drive shaft 451 and the second drive shaft 452 are connected through openings exposed at both ends of the clutch 44 . It may have an inserted structure. The length of the clutch 44 is at least longer than the distance between the first drive shaft 451 and the second drive shaft 452, so that the first drive shaft 451 and the second drive shaft 452 are formed by the clutch 44. It may be configured to have a structure in which connection is possible.

In addition, a winding portion 443 recessed to a predetermined width may be formed on the outer surface of the clutch 44 . The wire 43 may be disposed on the winding part 443 , and the wire 43 may be wound according to the rotation of the clutch 44 . That is, the clutch 44 enables selective power transmission so that the wire 43 can be wound as well as the selective rotation of the pinion 42 . And through the operation of the clutch 44, the drawer device can be drawn in and out and the inner accommodating part 34 can be moved up and down.

Hereinafter, an operation of the drawer device according to an embodiment of the present invention having the above structure will be described.

7 is a view sequentially illustrating the operation of the clutch. And, Figure 8 is a cross-sectional view showing a state in which the drawer device is retracted. And, Figure 9 is a cross-sectional view showing a state in which the drawer device is drawn out. And, Figure 10 is a cross-sectional view showing a state in which a part of the drawer device is raised.

When the freezing chamber door 30 is closed, as shown in FIG. 8 , the storage member 31 constituting the drawer device is completely retracted into the freezing chamber 13 . And, in this state, the clutch 44 may be in a state in which the first drive shaft 451 and the second drive shaft 452 are connected as shown in FIG. 6A . The rotational force of the first drive shaft 451 may be transmitted to the second drive shaft 452 by the clutch 44, and when the motor 41 is driven, the first drive shaft 451 and the second drive shaft ( 452) are connected so that they can be rotated together.

That is, the first drive shaft 451 and the second drive shaft 452 are inserted into the hollow inside of the clutch 44, and both the first screw part 451a and the second screw part 452a are of the clutch 44. It may be in a state of being screwed with the screw coupling portion 442 . In such a state, the user can input the automatic withdrawal and elevating operation of the drawer device by manipulating the operation unit 231 or the handle operation unit 321 .

First, a manipulation signal is transmitted by the user's manipulation input. In addition, when the motor 41 is driven by a manipulation signal, the motor 41 may rotate the first drive shaft 451 , and the second motor 41 connected to enable transmission of power by the clutch 44 . The two drive shafts 452 can also be rotated together. And, as the second drive shaft 452 rotates, the pinion 42 also rotates, and the pinion 42 moves along the rack part 133 . Meanwhile, in FIG. 6A , the rotation direction of the motor 41 may be defined as a forward direction, and as the motor 41 rotates in the forward direction, the clutch 44 moves toward the motor 41 . will do

The pinion 42 continuously moves along the rack part 133 and moves forward together with the drawer unit along the rack part 133 until the drawer unit is completely withdrawn. As shown in FIG. 9 , in a state in which the drawer device is drawn out, the accommodating member 31 is exposed to the outside of the cabinet.

And, in the state in which the drawer device is completely drawn out as shown in FIG. 9 , the clutch 44 moves until it comes into contact with the stopper 451b as shown in FIG. 6B . That is, the position of the stopper 451b and the length of the first screw portion 451a may be formed to have the same state as in FIG. 6(b) in a state in which the drawer device is completely drawn out.

On the other hand, since the clutch 44 does not rotate and moves along the drive shaft 45 until the state of FIG. 6B is reached, the wire 43 cannot be wound around the clutch 44. , the inner accommodating part 34 maintains the lowest height state.

As shown in FIG. 6B , in a state in which the clutch 44 is moved to the stopper, the coupling between the second screw part 452a and the screw coupling part 442 is released, and the hollow of the clutch 44 is released. An uncoupled portion 452b of the second driving shaft 452 is positioned inside the 441 .

That is, in this state, even when the motor 41 is driven, the second driving shaft 452 does not rotate, and the pinion 42 also does not rotate, so that the drawer device is maintained in a stopped state.

In addition, as shown in FIG. 6B , in a state in which the clutch 44 comes into contact with the stopper 451b and movement is restricted, it may be rotated together when the motor 41 is driven, and the internal accommodation part 34 ), the force to lift it can be applied. Accordingly, the clutch 44 rotated together with the motor 41 can wind up the wire 43 .

That is, when the clutch 44 comes into contact with the stopper 451b and does not rotate even when a load is applied through the wire, the winding portion 443 is attached to the wire 43 according to the rotation of the clutch 44 . ) is wound and is in a state as shown in (c) of FIG. 6 . The motor 41 continuously rotates forward, and only the clutch 44 rotates while the pinion 42 does not rotate to wind the wire 43 .

Accordingly, the wire 43 pulls the lower pulley 462 to move the inner accommodating part 34 upward, and the accommodating part frame 341 supports the inner accommodating part 34 in a state where it is supported. will move upwards. The inner accommodating part 34 is moved upward until the wire 43 is completely wound around the winding part 443, and the internal accommodating part 34 is shown in FIG. 10 along the elevating guide 311. As shown, it can be ascended to the maximum ascent point. In addition, in a state in which the inner accommodating part 34 is maximally raised, the user can perform the accommodating operation without bending the waist or lifting the food.

On the other hand, after the user completes the food storage operation, by manipulating the manipulation unit 231 or the handle manipulation unit 321, the user may input an operation for lowering and retracting the drawer device.

When an operation signal of the motor 41 is input through the manipulation unit 231 or the handle manipulation unit 321 , the motor 41 rotates in the reverse direction. That is, the motor 41 is configured to rotate in a direction opposite to the direction when the drawer device is withdrawn.

Due to the reverse rotation of the motor 41 , the clutch 44 also rotates in the reverse direction and moves toward the pinion 42 . By the reverse rotation of the clutch 44, the wire 43 that has been wound around the winding part 443 is unwound again, and as the transmission member is released, the inner receiving member 31 moves downward. will move

On the other hand, rotation cannot be transmitted to the second drive shaft 452 until the clutch 44 is coupled with the second screw portion 425a of the second drive shaft 452, and thus, in FIG. 6(d) As the wire 43 is continuously unwound until the state is reached, the inner receiving part 34 is moved downward.

In the state of FIG. 6 (d), the inner housing part 34 is completely lowered and the lowering is completed to be in the same state as in FIG. 9, and when the motor 41 is further rotated in the reverse direction in the state of FIG. , the screw coupling portion 442 of the clutch 44 and the second screw portion 425a start to be coupled to each other.

As the motor 41 rotates, the clutch 44 moves toward the pinion 42 , and the first drive shaft 451 and the second drive shaft 452 are connected again by the clutch 44 . In this state, the pinion 42 can rotate according to the rotation of the motor 41 . The pinion 42 moves rearward along the rack part 133 , and the drawer device can be retracted.

As the reverse rotation of the motor 41 is continuously made, the clutch 44 moves toward the pinion 42 until the state shown in FIG. will be in the same state At this time, the freezing chamber door 30 may shield the freezing chamber, and the housing member 31 may be fully retracted into the freezing chamber 13 .

Through this sequence, the drawer device can be lifted from the freezer compartment 13 and then the internal storage part 34 is raised. After the food storage is completed, the internal storage part 34 is lowered again. It is drawn into the inside of the freezing chamber 13 to complete the operation for storing food.

That is, the drawer device can be lifted after automatic withdrawal by the user's manipulation, and the drawer device can easily store food by performing a continuous operation of being drawn in after being lowered again by the user's manipulation.

Meanwhile, the present invention may be capable of various other embodiments in addition to the above-described embodiments. Hereinafter, other embodiments of the present invention will be described with reference to each drawing. In addition, in each of the other embodiments, the same reference numerals are used for the same components as those of the above-described embodiments, and detailed descriptions thereof will be omitted.

It is a perspective view showing the structure of a drawer device and a drive assembly according to another second embodiment of the present invention.

As shown in the drawings, the drawer device according to the third exemplary embodiment of the present invention may include a storage member 31 and an internal storage unit 34 having a structure capable of elevating therein. The inner accommodating part 34 may be moved up and down according to the operation of the driving assembly 40 ′, and may move up and down along the lifting guides 311 formed on both sides of the inside of the accommodating member 31 . In addition, storage member covers 312 may be provided on both sides of the storage member 31 to cover at least a portion of the driving assembly 40 ′.

The drive assembly 40' includes a single motor 40', a clutch 44 provided in pairs on both sides of the motor 40', a pinion 42, a drive shaft 45', and the like. can be In addition, the pinion 42 may be seated on the rack part 133 disposed inside the cabinet, and is configured to move along the rack part 133 .

In detail, the motor 40' may be provided in the center of the rear surface of the housing member 31, and a pair of first driving shafts 451' may be provided on both sides of the motor 40'. Accordingly, the drive shaft 45' can rotate in the same direction by one motor 40'. In addition, a first screw thread 451a is formed on the first drive shaft 451 ′, and the clutch 44 provided on the left and right sides during the forward rotation of the motor 40 ′ approaches each other, that is, the motor 40 ′. ), and when the motor 40 ′ rotates in a reverse direction, the clutch 44 is configured to move in a direction away from each other, that is, in a direction toward the pinion 42 . In addition, a stopper 451b may be provided on the first drive shaft 451 ′ to limit the clutch 44 from being moved further in the direction of the motor 40 ′.

A second drive shaft 45' is connected to the other side of the clutch 44, and the pinion 42 is provided at an end of the second drive shaft 45'. In this case, the pinion 42 may be positioned on the rack part 133 , and may be moved along the rack part 133 according to the rotation of the second driving shaft 45 ′.

In addition, a second screw thread 452a and a non-coupled portion 452b may be formed on the second drive shaft 45 ′, and the clutch 44 may move with the second screw thread 452a according to the movement of the clutch 44 . It may have a structure in which the coupled or non-coupled portion 452b is inserted. Since the coupling relationship and action between the clutch 44 and the first drive shaft 451 ′ and the second drive shaft 45 ′ are the same as those of the above-described embodiment, a detailed description thereof will be omitted.

In addition, a wire 43 may be connected to the clutch 44 , and the wire 43 may be connected to a pulley 46 provided on both sides of the accommodation member 31 . The pulley 46 may have a structure connected to the internal receiving part 34 . And, through the process in which the clutch 44 winds up the wire 43, the inner accommodating part 34 may rise, and the clutch 44 reversely rotates to loosen the wound wire 43. When this occurs, the inner accommodating part 34 is lowered. The arrangement and coupling relationship of the pulley 46 and the wire 43 are the same as in the above-described embodiment, and the illustration is omitted.

In this structure, when the motor 40' rotates forward by the user's manipulation, the second drive shaft 45' and the pinion 42 connected by the clutch 44 rotate, and the rack part 133 ), the pinion 42 is moved so that the accommodating member 31 can be pulled out.

When the withdrawal of the housing member 31 is completed, the movement of the clutch 44 is restricted by the stopper 451b, and the clutch 44 is rotated together with the first drive shaft 451' to rotate the wire ( 43) will be rolled up. Accordingly, the inner receiving portion 34 can be raised.

And, when the motor 40 ′ rotates in a reversed state while the inner accommodation part 34 is raised, the wire 43 wound around the clutch 44 is unwound and the inner accommodation part 34 descends. will do In a state in which the inner accommodation part 34 is lowered, the clutch 44 may be connected to the second drive shaft 45' again, and the first drive shaft 451' and the second drive shaft are connected by the clutch 44. In a state in which 45' is reconnected, the housing member 31 can be completely retracted into the cabinet by the continuous reverse rotation of the motor 40'.

12 is a cutaway perspective view showing the structure of a drawer device and a drive assembly according to another third embodiment of the present invention.

As shown in the drawing, the drawer device according to the third embodiment of the present invention may include a storage member 31 and an internal storage unit 31 having a structure capable of elevating therein. The inner accommodating part 31 may be raised or lowered according to the operation of the driving assembly 40 ″, and may be supported by the accommodating part frame 341 . In addition, the inner accommodating part 31 may move up and down along the lifting guides 311 formed on both sides of the inner accommodating member 31 .

In addition, the rack part 313 may be formed on the upper end of both sides of the receiving member 31 . The rack part 313 may extend long in the front-rear direction of the accommodating member 31 , and the pinion 42 of the driving assembly 40 ″ may be seated thereon.

The driving assembly 40 ″ includes a motor 41 , a first driving shaft 451 mounted on the motor 41 , a pinion 42 mounted on the rack part 313 , and the pinion 42 . ) to rotate the second drive shaft 452, the clutch 44 connecting the first drive shaft 451 and the second drive shaft 452, and the wire 43 wound by the clutch 44 to guide It may include an upper pulley 461 and a lower pulley 462 .

The motor 41 is fixedly mounted on both left and right sides of the inner wall of the refrigerator, and provides power for rotation of the pinion 42 and the clutch 44 .

The first drive shaft 451 and the second drive shaft 452 are arranged on the same extension line, and in a state where they are connected by the clutch 44, the power of the motor 41 is transmitted to rotate the pinion 42 In a state in which the clutch 44 is moved to the motor 41 and disconnected from the second drive shaft 452, only the first drive shaft 451 is rotated so that the clutch 44 is connected to the wire 43. It may be configured to be wound.

The pinion 42 is rotated by the rotation of the motor 41, and the direction of movement of the rack part 313 is determined according to the forward and reverse rotation of the motor 41, so that the housing member 31 is drawn out or can be brought in

And, in the state in which the housing member 31 is completely drawn out, the clutch 44 is disconnected from the second drive shaft 452, and the internal number according to the forward or reverse rotation of the clutch 44 is released. The payment 31 is raised or lowered.

Since the operation method of the clutch 44, the rotation method of the pinion 42, and the winding structure of the wire 43 are the same as in the above-described embodiment, only the arrangement position of the motor 41 is different. A detailed description thereof will be omitted.

13 is an exploded view showing the coupling structure of the driving assembly according to the fourth embodiment of the present invention.

As shown, the motor 41, the first drive shaft 451, the clutch 44, the second drive shaft 452, and the pinion 42 constituting the drive assembly 40 according to the fourth embodiment of the present invention. may be continuously arranged on the same extension line. Through such an arrangement, the drawer device can be automatically drawn in and out according to the operation of the driving assembly 40 , and the internal accommodating part 34 of the drawer device can be raised and lowered.

The motor 41 may be fixedly mounted to the housing member 31 , and the first driving shaft 451 coupled to the motor 41 faces the drawer guide 132 on which the rack part 133 is formed. is extended A first screw portion 451a coupled to a screw coupling portion inside the clutch 44 may be formed on the first drive shaft 451 . The first screw portion 451a may be formed to be coupled to the screw coupling portion 442 .

Also, according to the rotation of the first driving shaft 451 , the clutch 44 may move along the first driving shaft 451 . Depending on the rotational direction of the motor 41 , the clutch 44 may move toward the motor 41 or toward the pinion 42 .

A second drive shaft 452 may be connected to the other side of the clutch 44 . The second drive shaft 452 may extend from the clutch 44 to the rack part 133 , and the pinion 42 may be mounted at an end of the second drive shaft 452 . In addition, the pinion 42 may have an outer peripheral surface formed in a gear shape corresponding to the rack part 133 so as to be coupled to the rack part 133 .

In addition, the second driving shaft 452 may be formed to have the same outer diameter as the first driving shaft 451 , and the second driving shaft 452 includes a rotating part 452b and a connecting part 452a in the longitudinal direction. can do.

The rotating part 452b has a circular cross section that can be inserted into the hollow 441 of the clutch 44 and extends from one end of the second drive shaft 452 to a predetermined distance. The length of the rotating part 452b may be such that the end of the clutch 44 is positioned inside the hollow 441 of the clutch 44 in a state in which the clutch 44 is moved to the motor 41 side as far as possible.

The connection part 452a may extend from one end of the rotation part 452b to the pinion 42 and may have a polygonal cross-sectional shape. The rotating part 452b may be formed in a shape corresponding to the opening 441b of the hollow 441 of the clutch 44, and therefore, in a state in which the connecting part 452a is inserted into the opening 441b, the clutch 44 and the second drive shaft 452 are rotatable together. Of course, the connecting portion 452a may be formed in a key-combinable shape capable of transmitting power rather than a polygonal shape. Meanwhile, the lengths of the connection part 452a and the rotation part 452b may be determined according to the stroke of the clutch 44 .

The clutch 44 is formed in a cylindrical shape with hollows 441 passing through both ends, and the first drive shaft 451 and the second drive shaft 452 are connected through openings exposed at both ends of the clutch 44 . It may have an inserted structure. At this time, the opening 441a on one side into which the first driving shaft 451 is inserted is formed in a circular shape corresponding to the first driving shaft 452, and the opening 441b on the other side into which the second driving shaft 452 is inserted. may be formed in a polygonal shape corresponding to the second driving shaft 452 .

In addition, the length of the clutch 44 is formed to be at least longer than the distance between the first drive shaft 451 and the second drive shaft 452, so that the first drive shaft 451 and the second drive shaft 451 and the second drive shaft by the clutch 44 ( 452) may be configured to have a structure capable of being connected.

In addition, a winding portion 443 recessed to a predetermined width may be formed on the outer surface of the clutch 44 . The wire 43 may be disposed on the winding part 443 , and the wire 43 may be wound according to the rotation of the clutch 44 . That is, the clutch 44 enables selective power transmission so that the wire 43 can be wound as well as the selective rotation of the pinion 42 . And through the operation of the clutch 44, the drawer device can be drawn in and out and the inner accommodating part 34 can be moved up and down.

Hereinafter, an operation state of a clutch according to a fourth embodiment of the present invention having the above configuration will be described with reference to the drawings.

14 is a view sequentially illustrating the operation of the clutch of the drive assembly.

As shown in the drawing, in a state in which the housing member 31 constituting the drawer device is completely retracted into the freezing compartment 13, the clutch 44 is operated as shown in FIG. 14(a). , the first driving shaft 451 and the second driving shaft 452 may be connected in a state in which power transmission is possible.

That is, the first drive shaft 451 and the second drive shaft 452 may be inserted into the hollow of the clutch 44 . In addition, the first screw portion 451a is in a state of being screwed with the screw coupling portion 442 , and the second drive shaft 452 is connected to the opening 441b of the clutch 44 by the connection portion 452a. is inserted.

In such a state, when the motor 41 is driven by a manipulation signal, the motor 41 may rotate the first drive shaft 451 , and the clutch 44 enables power to be transmitted. The connected second drive shaft 452 may also be rotated together. And, as the second drive shaft 452 rotates, the pinion 42 also rotates, and the pinion 42 moves along the rack part 133 . Meanwhile, in FIG. 14A , the rotation direction of the motor 41 may be defined as a forward direction, and as the motor 41 rotates in the forward direction, the clutch 44 moves toward the motor 41 . will do

In a state in which the drawer device is completely drawn out, the clutch 44 moves until it comes into contact with the stopper 451b as shown in FIG. 14(b). And, since the clutch 44 is not rotated and moves along the drive shaft 45 until such a state is reached, the wire 43 cannot be wound around the clutch 44, and the inner receiving part (34) will maintain the lowest height state.

As shown in FIG. 14(b), in a state in which the clutch 44 is moved to the stopper 451b, the coupling between the connection part 452a and the opening 441b is released, and the hollow ( 441), that is, inside the opening 441b, the rotating part 452b is located.

That is, in this state, even when the motor 41 is driven, power is not transmitted to the second driving shaft 452 , and the pinion 42 is also not rotated, so that the drawer device is maintained in a stopped state. .

And, in a state where the clutch 44 is in contact with the stopper 451b and the movement is restricted as shown in FIG. 14(b), the clutch 44 may be rotated together when the motor 41 is driven. , it is possible to take a force to lift the inner receiving part (34). Accordingly, the clutch 44 rotated together with the motor 41 can wind up the wire 43 .

That is, when the clutch 44 comes into contact with the stopper 451b and does not rotate even when a load is applied through the wire, the winding portion 443 is attached to the wire 43 according to the rotation of the clutch 44 . ) is wound, and it is in a state as shown in FIG. 14(c). The motor 41 continuously rotates forward, and only the clutch 44 rotates while the pinion 42 does not rotate to wind the wire 43 .

As the wire 43 is wound, the inner accommodating part 34 is moved upward. The inner accommodating part 34 is moved upward until the wire 43 is completely wound around the winding part 443 , and may be raised to a maximum rising point. In addition, in a state in which the inner accommodating part 34 is maximally raised, the user can perform the accommodating operation without bending the waist or lifting the food.

When the operation signal of the motor 41 for lowering the inner accommodating part 34 and retracting the accommodating member 31 is input, the motor 41 rotates in the reverse direction.

Due to the reverse rotation of the motor 41 , the clutch 44 also rotates in the reverse direction and moves toward the pinion 42 . By the reverse rotation of the clutch 44, the wire 43 that has been wound around the winding part 443 is unwound again, and as the transmission member is released, the inner receiving member 31 moves downward. will move

On the other hand, rotation cannot be transmitted to the second drive shaft 452 until the clutch 44 is coupled with the connection portion 452a of the second drive shaft 452, and thus, the state (d) of FIG. 14 is As the wire 43 is continuously unwound until the

In the state of (d) of FIG. 14 , the inner accommodation part 34 is completely descended to complete the descending and when the motor 41 further rotates in the reverse direction, the connection part is inside the opening 441b of the clutch 44 . 452a is inserted and begins to engage with each other.

As the motor 41 rotates, the clutch 44 moves toward the pinion 42 , and the first drive shaft 451 and the second drive shaft 452 are connected again by the clutch 44 . In this state, the pinion 42 can rotate according to the rotation of the motor 41 . The pinion 42 moves rearward along the rack part 133 , and the drawer device can be retracted.

15 is an exploded view showing the coupling structure of the driving assembly according to the fifth embodiment of the present invention.

As shown, the motor 41, the first drive shaft 451, the clutch 44, the second drive shaft 452, and the pinion 42 constituting the drive assembly 40 according to the fifth embodiment of the present invention. may be continuously arranged on the same extension line. Through such an arrangement, the drawer device can be automatically drawn in and out according to the operation of the driving assembly 40 , and the internal accommodating part 34 of the drawer device can be raised and lowered.

The motor 41 may be fixedly mounted to the housing member 31 , and the first driving shaft 451 coupled to the motor 41 faces the drawer guide 132 on which the rack part 133 is formed. is extended A first screw portion 451a coupled to the screw coupling portion 442 inside the clutch 44 may be formed on the first drive shaft 451 . The first screw portion 451a may be formed to be coupled to the screw coupling portion 442 .

Also, according to the rotation of the first driving shaft 451 , the clutch 44 may move along the first driving shaft 451 . Depending on the rotational direction of the motor 41 , the clutch 44 may move toward the motor 41 or toward the pinion 42 .

In addition, a stopper 455 may be formed outside the first screw portion 451a. The stopper 455 extends along the circumference of the first drive shaft 451 , and when the clutch 44 moves toward the pinion 42 , it may limit the movement of the pinion 42 .

A restraining member 456 may be provided on the first driving shaft 451 extending past the stopper 455 . The restraining member 456 may be rotatably mounted to the first driving shaft 451 by a hinge device 457 . The restraining member 456 may include a contact portion 456a extending beyond the stopper 455 and an insertion portion 456b inserted into the restraining portion 452c formed on the second driving shaft 452 .

The contact portion 456a may be pressed by the clutch 44 when the clutch 44 is moved, and when the clutch 44 is pressed, the restraining member 456 moves the hinge device 457 as an axis. will rotate to By rotation of the restraining member 456 , the insertion part 456b may come out of the restraining part 452c. As such, the constraining member 456 may be selectively inserted into the constraining part 452c by rotation, and the first driving shaft 451 and the second driving shaft 452 may be inserted into the constraining part 452c by insertion. can be rotated together.

Meanwhile, an elastic member 458 may be further provided between one side of the insertion part 456b and the first driving shaft 451 . The restraining member 456 by the elastic member 458 is inserted into the restraining portion 452c to maintain a restrained state unless an external force is provided.

In addition, the hinge device 457 may be configured as a damping hinge, and after the restraining member 456 is separated from the restraining portion 452c, the external force is removed and inserted back into the restraining portion 452c. Allow it to rotate slowly with a predetermined time. In this case, the predetermined time may be a time for all the wires 43 to be released by the rotation of the clutch 44 to complete the lowering of the internal housing 34 .

A second driving shaft 452 may be disposed on one side spaced apart from the first driving shaft 451 . The second driving shaft 452 may be positioned on the same extension line as the first driving shaft 451 . In addition, the second driving shaft 452 may extend to the rack part 133 , and the pinion 42 may be mounted to an end of the second driving shaft 452 . In addition, the pinion 42 may have an outer peripheral surface formed in a gear shape corresponding to the rack part 133 so as to be coupled to the rack part 133 .

On the other hand, on the second drive shaft 452, the constraining member 456 may be rotated to be inserted into the constraint portion 452c may be formed. The restraining part 452c may be formed in a groove shape corresponding to the insertion part 456b, and when the restraining member 456 is rotated, the restraining member 452c may be engaged with each other, thereby providing the power of the first driving shaft 451. to be transmitted to the second driving shaft 452 .

The clutch 44 is formed in a cylindrical shape in which a hollow 441 through which the first drive shaft 451 passes is formed, and the first drive shaft 451 is inserted into an opening exposed at both ends of the clutch 44 can have a structure.

In addition, a winding portion 443 recessed to a predetermined width may be formed on the outer surface of the clutch 44 . The wire 43 may be disposed on the winding part 443 , and the wire 43 may be wound according to the rotation of the clutch 44 . That is, the clutch 44 enables selective power transmission so that the wire 43 can be wound as well as the selective rotation of the pinion 42 . And through the operation of the clutch 44, the drawer device can be drawn in and out and the inner accommodating part 34 can be moved up and down.

Hereinafter, an operation state of a clutch according to a fifth embodiment of the present invention having the above configuration will be described with reference to the drawings.

16 is a view sequentially illustrating the operation of the clutch of the drive assembly.

As shown in the drawing, in a state in which the housing member 31 constituting the drawer device is completely retracted into the freezing compartment 13, the clutch 44 is operated as shown in FIG. 14(a). , located at an end of the first screw portion 451a of the first drive shaft 451 . In addition, the first driving shaft 451 and the second driving shaft 452 may be connected in a state in which power transmission is possible.

That is, the first driving shaft 451 and the second driving shaft 452 may be connected in a state in which the insertion part 456b of the restraining member 456 is inserted inside the restraining part 452c. . And, the restraining member 456 by the elastic member 458 maintains the restrained state with the restraining portion 452c unless an external force is applied.

In such a state, when the motor 41 is driven by a manipulation signal, the motor 41 may rotate the first driving shaft 451 , and power may be transmitted by the restraining member 456 . The second drive shaft 452 connected to each other may also be rotated together. And, as the second drive shaft 452 rotates, the pinion 42 also rotates, and the pinion 42 moves along the rack part 133 . Meanwhile, in FIG. 16A , the rotation direction of the motor 41 may be defined as a forward direction, and as the motor 41 rotates in the forward direction, the clutch 44 moves toward the motor 41 . will do

In a state in which the drawer device is completely drawn out, the clutch 44 moves until it comes into contact with the stopper 455 as shown in FIG. 16(b). And, since the clutch 44 is not rotated and moves along the first drive shaft 451 until such a state is reached, the wire 43 cannot be wound around the clutch 44, and the inner The accommodating part 34 maintains the lowest height state.

As shown in FIG. 16B , when the clutch 44 is moved to the stopper 455 , it comes into contact with the contact portion 456a of the restraining member 456 extending beyond the stopper 455 . In a state in which the clutch 44 is fully moved to the stopper 455, the contact portion 456a is completely pressed, and the restraint member 456 is rotated to move from the restraint portion 452c to the insertion portion 456b. may be in an exited state. The first driving shaft 451 and the second driving shaft 452 may be separated from each other by the rotation of the restraining part 452c.

That is, in this state, even when the motor 41 is driven, power is not transmitted to the second driving shaft 452 , and the pinion 42 is also not rotated, so that the drawer device is maintained in a stopped state. .

As shown in (b) of FIG. 16 , in a state in which the clutch 44 is pressing the contact portion 456a, the restraining member 456 maintains a state separated from the restraining portion 452c. In addition, the clutch 44 is no longer moved by the contact portion 456a and the stopper 455 , and the clutch 44 may be rotated together when the motor 41 is driven, and the internal accommodation portion (34) It becomes possible to take the force to lift it. Accordingly, the clutch 44 rotated together with the motor 41 can wind up the wire 43 .

That is, when the clutch 44 comes into contact with the stopper 451b and does not rotate even when a load through the wire 43 is applied, the winding portion 443 is placed on the winding portion 443 according to the rotation of the clutch 44 . The wire 43 is wound and becomes the state as shown in FIG. 16(c). The motor 41 continuously rotates forward, and only the clutch 44 rotates while the pinion 42 does not rotate to wind the wire 43 .

As the wire 43 is wound, the inner accommodating part 34 is moved upward. The inner accommodating part 34 is moved upward until the wire 43 is completely wound around the winding part 443 , and may be raised to a maximum rising point. In addition, in a state in which the inner accommodating part 34 is maximally raised, the user can perform the accommodating operation without bending the waist or lifting the food.

When the operation signal of the motor 41 for lowering the inner accommodating part 34 and retracting the accommodating member 31 is input, the motor 41 rotates in the reverse direction.

Due to the reverse rotation of the motor 41, the clutch 44 also rotates in the reverse direction. By the reverse rotation of the clutch 44, the wire 43 that has been wound around the winding part 443 is unwound again, and as the transmission member is released, the inner receiving member 31 moves downward. will move

When the clutch 44 rotates in the reverse direction, the clutch 44 may be partially moved toward the motor 41 . At this time, the contact between the contact portion 456a of the restraining member 456 and the clutch 44 is released. can However, due to the damping of the hinge device 457, the constraining member 456 rotates slowly, and only after a time for the internal accommodation part 34 to be completely lowered has elapsed. A portion 456b may be inserted into the restraining portion 452c. Since rotation cannot be transmitted to the second driving shaft 452 until the restraining member 456 is restrained by the restraining portion 452c of the second driving shaft 452, the receiving member 31 is drawn out. will keep

In the state of FIG. 16 (d), the inner receiving part 34 is completely lowered and the insertion part 456b of the restraining member 456 is inserted into the restraining part 452c in a state where the lowering is completed, , the restraining member 456 can be restrained by the restraining portion 452c.

In this state, the first drive shaft 451 and the second drive shaft 452 are connected again as shown in FIG. 16(e) so that the pinion 42 can rotate according to the rotation of the motor 41. do. The pinion 42 moves rearward along the rack part 133 , and the drawer device can be retracted.

17 is a view showing the configuration of a driving assembly according to a sixth embodiment of the present invention.

As shown in the drawings, the drive assembly 40 according to the sixth embodiment of the present invention includes a motor 41 , a motor gear 47 , a drive shaft 453 , a drive gear 48 , and a clutch 49 . , it may be configured to include a pinion (42).

Looking at this in more detail, the motor 41 is mounted on the accommodating member 31 , and provides power for drawing in and out of the accommodating member 31 and elevating the inner accommodating part 34 . And a motor gear 47 is mounted on the motor shaft 411 of the motor 41 and rotates together when the motor 41 is driven.

The motor gear 47 may include a first motor gear 471 and a second motor gear 472, and the first motor gear 471 and the second motor gear 472 may be spaced apart from each other. have. The first motor gear 471 and the second motor gear 472 may be integrally molded, or may be configured to be spaced apart from each other on the motor shaft 411 after being molded. In addition, the first motor gear 471 has a larger diameter than the second motor gear 472 and is positioned closer to the motor 41 .

The driving shaft 453 may be disposed parallel to the motor shaft 411 and may extend to the rack part 133 formed on the inner sidewall of the refrigerator. The drive gear 48 , the clutch 49 , and the pinion 42 may all be mounted on the drive shaft 453 .

Meanwhile, the driving shaft 453 is formed in a single shaft structure, but may have structures having different cross-sectional shapes. In detail, the driving shaft 453 includes a first driving part 453a extending from one end close to the motor 41 and having a polygonal cross-sectional shape, and extending from the first driving part 453a to the pinion 42 side, and has a circular shape. It may be composed of a second driving unit 453b having a cross-section. Accordingly, the first driving gear 481 mounted on the first driving unit 453a may rotate together with the driving shaft 453, and the second driving gear 482 mounted on the second driving unit 453b and The clutch 49 may be rotated independently of the drive shaft 453 about the drive shaft 453 .

In addition, the driving gear 48 may include a first driving gear 481 and a second driving gear 482 . The first driving gear 481 and the second driving gear 482 may be spaced apart from each other, and the diameter of the first driving gear 481 may be smaller than the diameter of the second driving gear 482 . have. And, the driving gear 48, that is, the first driving gear 481 and the second driving gear 482 can slide along the driving shaft, and the first driving gear 481 is the first motor gear ( 471 ) and the second driving gear 482 may be selectively connected to the second motor gear 472 . That is, the first driving gear 481 and the second driving gear 482 are connected to the first motor gear 471 or the second motor gear 472 depending on the state of sliding along the driving shaft 453 . ) can be connected to

In detail, the first driving gear 481 may be mounted on the first driving unit 453a. At this time, as in the cross section A-A', the center of the first driving gear 481 may be formed in the same polygonal shape as the cross-section of the first driving part 453a, and therefore, when the driving shaft 453 rotates, the 1 The driving gear 481 may be rotated together. In other words, in a state in which the first driving gear 481 and the first motor gear 471 are connected, the driving shaft 453 may be rotated when the motor 41 is driven, and the rotational force through the driving shaft 453 . transmission is possible. In addition, the first driving part 453a is formed to have a predetermined width so that the first driving gear 481 can slide along the driving shaft 453 toward the pinion 42 to enable the first driving. It is possible to selectively connect the gear and the first motor gear 471 .

On the other hand, a first connection part 481a protruding toward the pinion 42 may be formed on one side of the first driving gear 481, and a second connection part on which the second driving gear 482 is mounted ( 482a). Accordingly, when the first driving gear 481 and the second driving gear 482 are slidably moved along the driving shaft 453 , they may be moved while maintaining a predetermined distance from each other.

Meanwhile, the second driving gear 482 may be mounted on the second connection part 482a mounted on the second driving part 453b. The second connection part 482a is formed so that the inside is hollow, and is mounted on the second driving part 453b of the circular cross-section as seen in section B-B', so that the second driving part 453b is free as an axis. It may be configured to be rotatable.

In addition, one end of the second connection part 482a facing the motor 41 is coupled to the first connection part 481a, and the first driving gear 481 and the second driving gear 482 are connected to each other. so that they can slide together. The first connection part 481a and the second connection part 482a may be rotatably connected to each other, and thus, the first driving gear 481 and the second driving gear 482 may rotate independently.

In addition, a clutch 49 may be disposed at the other end of the second connection part 482a facing the pinion 42 . Accordingly, the second connection portion 482a and the clutch 49 may be configured to slide and rotate together along the drive shaft 453 .

The second driving gear 482 is disposed on the second connection part 482a and may be formed to have a larger diameter than that of the first driving gear 481 . In this case, the diameter of the second driving gear 482 may be formed to a size that can be engaged with the second motor gear 472 when the second driving gear 482 is slidingly moved.

Meanwhile, a drive shaft sleeve 454 may be formed inside the second connection part 482a. The driving shaft sleeve 454 may be formed so that a center thereof is penetrated by the driving shaft 453 , and the driving shaft 453 may be formed to rotate and slide inside the driving shaft sleeve 454 . The drive shaft sleeve 454 may be formed of a material with low friction, and may facilitate sliding and rotation of the second drive gear 482 and the clutch 49 disposed on the drive shaft 453 . In addition, the drive shaft sleeve 454 may extend to one end of the clutch 49 through the hollow 491 of the clutch 49 inside the first connection part 481a.

The clutch 49 may be coupled to the second connection part 482a or may be formed integrally with the second connection part 482a. At least one of the second driving gear 482, the second connection part 482a, and the clutch 49 is integrally formed to form the second driving gear 482, the second connection part 482a, and the clutch ( 49) can be configured to rotate together when rotating forward and reverse.

In addition, a winding portion 492 recessed along the circumference may be formed in the clutch 49 . The winding portion 492 provides a space in which the wire 46 for lifting and lowering the housing member 31 can be wound. Accordingly, the wire 46 may be wound or unwound depending on the rotational direction of the clutch 49 , and through this, the accommodation member 31 may be lifted or lowered.

The stopper 493 may be provided at one side of the clutch 49 . The stopper 493 may support the clutch 49 and may have a rotational connection structure by a bearing 494 . Accordingly, the clutch 49 may be rotatably supported by the stopper 493 .

The stopper 493 may be formed in a plate shape having a predetermined size, and at least a portion of the stopper 493 may be formed of a metal material that can be attached to a magnet. The stopper 493 is the end of the rack part 133 when the pinion 42 moves along the rack part 133, that is, when the accommodating member 31 reaches a fully drawn out position. It may be formed to be attached to the magnet (133a) provided on the rack part (133).

That is, the stopper 493 is spaced apart from the rack part 133 and maintains a predetermined distance while the accommodating member 31 is pulled out and pulled out, and the stopper 493 at the moment the accommodating member 31 is completely withdrawn. ) may be attached by moving toward the rack part 133 by the magnet. At this time, both the drive gear 48 and the clutch 49 on the drive shaft 453 as well as the stopper 493 slide along the drive shaft 453 toward the rack part 133 , and at this time, the motor gear 47 ) and the conversion of the connection relationship between the driving gear 48 is made.

In addition, the magnet 133a may be configured as an electromagnet, and may selectively enable horizontal movement of the stopper 493 . That is, when it is necessary to change the connection relationship between the motor gear 47 and the driving gear 48 , the magnet 133a may selectively generate a magnetic force to move the stopper 493 .

An elastic member 456 may be provided on one side of the stopper 493 . The elastic member 456 may provide an elastic force so that the stopper 493 is separated from the magnet 133a and returned to its original position. To this end, one end of the elastic member 456 may be in contact with the stopper 493 , and the other end may be in contact with the elastic member support 421 fixed on the driving shaft 453 . The elastic member support part 421 may be fixedly mounted on the driving shaft 453 as a separate material, or may be integrally formed with the pinion 42 .

A pinion 42 may be mounted at an end of the driving shaft 453 . The pinion 42 may be mounted on the driving shaft 453 so that it can be rotated together when the driving shaft 453 rotates. And, it is seated on the upper end of the rack part 133 , and is gear-coupled with the gear teeth 133b of the rack part 133 so as to be moved back and forth along the rack part 133 .

Hereinafter, the operation of the driving assembly 40 according to an embodiment of the present invention having the above configuration will be described with reference to the drawings.

18 to 21 are views sequentially illustrating the operation of the clutch of the drive assembly.

In a state in which the housing member 31 is completely drawn into the interior space before the user's operation, the driving assembly 40 is in a state as shown in FIG. 17 . At this time, the first motor gear 471 is connected to the first driving gear 481 .

In this state, when the user inputs the drawer device withdrawal and lift operation, the motor 41 is driven and the drive shaft 453 is driven by the first motor gear 471 and the first drive gear 481 . will rotate in the forward direction. When the driving shaft 453 rotates in the forward direction, the pinion 42 connected to the driving shaft 453 also rotates in the forward direction, and moves forward along the rack part 133 so that the receiving member 31 is pulled forward. can proceed.

At this time, the second driving gear 482 is not connected to the second motor gear 472, and the second driving gear 482 and the clutch 49 are located in the second driving unit 453b. Since the power of the driving shaft 453 is not transmitted, it is not rotated. Accordingly, the winding of the wire 46 is not performed, and only the drawing operation of the accommodating member 31 is performed.

When the receiving member 31 is fully drawn out, as shown in FIG. 18 , the pinion 42 reaches the end of the rack part 133 or a specific position of the rack part 133 . At this time, a magnet is disposed on the rack part 133 , and power is applied to the magnet 133a to generate a magnetic force. In order to generate the magnetic force of the magnet 133a, power may be applied when the accommodating member 31 is pulled out, or may be applied when the pinion 42 reaches a specific position. When a magnetic force is generated from the magnet 133a, the stopper 493 moves toward the rack part 133 by the magnetic force.

The elastic member 456 supporting the stopper 493 may be in a compressed state by the movement of the stopper 493 . In addition, the second connection part 482a and the first driving gear 481 connected to the second connection part 482a and the clutch 49 both horizontally move toward the pinion 42 . That is, both the drive gear 48 and the clutch 49 on the drive shaft 453 slide toward the pinion 42 along with the movement of the stopper 493 .

Accordingly, as shown in FIG. 18 , the motor gear 47 and the driving gear 48 may be switched to a state in which the second motor gear 472 and the second driving gear 482 are coupled to each other. Then, the second driving gear 482 can be rotated by the driving of the motor 41 . At this time, the motor 41 maintains the rotational direction, and it is possible to maintain a continuous rotational state even when the connection between the motor gear 47 and the driving gear 48 is switched. Accordingly, the motor 41 can perform continuous rotation from the withdrawal of the housing member 31 to the lifting and lowering of the inner housing part 34 , and the clutch 49 is rotated during the rotation of the motor 41 . By the movement, the connection conversion between the motor gear 47 and the driving gear 48 may be made.

19, the second driving gear 482 rotates in the forward direction by the continuous rotation of the motor 41, and the clutch 49 connected to the second driving gear 482 rotates in the forward direction. will rotate The wire 46 may be wound by the forward rotation of the clutch 49 , and the inner accommodation part 34 of the accommodation member 31 may be raised by winding the wire 46 . When the internal accommodating part 34 is completed, the user can store food in a more comfortable posture without bending his or her back much.

When the user inputs a lowering and retracting operation of the drawer device in a state in which the inner receiving part 34 is raised, the motor 41 starts to be driven. At this time, as shown in FIG. 20 , the motor 41 rotates in the opposite direction to when the housing member 31 is pulled out and the inner housing part 34 is raised. Accordingly, the second driving gear 482 rotates in the reverse direction, and the clutch 49 also rotates in the reverse direction. As the clutch 49 rotates in the reverse direction, the wire 46 wound around the clutch 49 is unwound again, and the inner receiving part 34 is lowered.

The motor 41 may be driven by a sensor device that detects the height of the driving time control or the internal housing 34, and is stopped when the internal housing 34 rises or descends to a set height. can

On the other hand, since both the second driving gear 482 and the clutch 49 are connected to the second driving part 453b of the driving shaft 453 and rotatable independently of the driving shaft 453 , the driving shaft 453 is ) does not transmit power. Accordingly, while the wire 46 is wound or unwound, the pinion 42 is not rotated while the inner accommodating part 34 is elevating.

Then, when the lowering of the inner accommodating member 31 is completed and the wire 46 wound around the clutch 49 is completely released, the power applied to the magnet 133a is cut off, and the magnet 133a ), no magnetic force is provided.

At this time, the determination of the state in which the wire 46 is completely unwound may be determined through the driving time of the motor 41 or the load of the motor, and the detection of the position of the internal accommodating part 34 .

As shown in FIG. 21 , when the magnetic force is not provided through the magnet 133a , the restraint force of the stopper 493 is released and the stopper 493 is supported by the elastic force of the elastic member 456 . The clutch 49 and the driving gear 48 that are used are slidingly moved along the driving shaft 453 .

When the first clutch 49 slides in the motor 41 direction, the driving gear 48 also moves in the motor direction, and the first motor gear 471 and the first driving gear ( 481) can be engaged with each other.

When the motor 41 rotates in a state in which the first motor gear 471 and the first driving gear 481 are meshed with each other, the first driving gear 481 rotates in reverse, and the driving shaft 453 The pinion 42 connected to the also rotates in reverse. The pinion 42 moves rearward along the rack part 133 , so that the accommodating member 31 can be retracted to the inside of the cabinet.

When the retraction of the housing member 31 is completed, the motor 41 may stop driving to complete the operation. In this case, the completion of the driving of the motor 41 may be achieved by controlling the driving time of the motor 41 or a sensing device for detecting the position of the housing member 31 .

23 is a front view of a refrigerator according to a seventh embodiment of the present invention. And, FIG. 24 is a view in which the door of the refrigerator is opened.

As shown in the drawing, the refrigerator 2 according to the seventh embodiment of the present invention has a cabinet 50 in which an upper storage space 52 and a lower storage space 53 partitioned up and down by a barrier 51 are formed. ) and an upper door 61 and a lower door 62 for opening and closing the upper storage space 52 and the lower storage space 53, respectively.

A pair of the upper doors 61 may be provided, and the pair of upper doors 61 may be independently rotatably mounted to the cabinet 50 . Accordingly, the upper storage space 52 can be partially opened and closed by each of the upper doors 61 .

The lower storage space 53 may be partitioned on left and right sides by a vertical wall 531 . A pair of the lower doors 62 may be provided, and the pair of lower doors 62 may be independently rotatably mounted to the cabinet 50 . Accordingly, the lower door 62 can individually open and close the partitioned left and right spaces of the lower storage space 53 .

Meanwhile, a display 611 for displaying the operating state of the refrigerator 2 may be provided on the front surface of the upper door 61 . In addition, a manipulation unit 612 for manipulating the operation of the refrigerator 2 may be further formed on the display 611 .

The automatic opening and closing of the lower door 62 will be possible by the operation of the manipulation unit 612 , and the storage member 70 disposed in the lower storage space 53 in connection with the automatic opening and closing of the lower door 62 . Automatic withdrawal and elevation of the internal storage unit 71 inside the storage member 70 may be continuously performed. Of course, the operation unit 612 may be operated such that the opening and closing of the lower door 62 , the withdrawal of the storage member 70 , and the elevation of the internal storage unit 71 are performed independently.

Meanwhile, the accommodating member 70 may be provided inside the lower storage space 53 . The accommodating member 70 may be configured to be withdrawable in a drawer manner. A driving assembly 40 may be provided at the rear of the receiving member 70 for drawing in and out of the receiving member 70 and lifting and lowering the inner receiving part 71 inside the receiving member 70 . The configuration of the driving assembly 40 may be any one of the above-described embodiments.

25 is a view showing a state in which the storage member of the refrigerator is withdrawn. And, Figure 26 is a cross-sectional view seen from the side of the drawing out of the storage member.

Referring to the drawings, referring to the accommodating member 70 and the driving assembly 40 in more detail, the accommodating member 70 may be provided inside the lower storage space 53 . The accommodating member 70 may have a structure such as a drawer that can be pulled out and formed in the shape of a basket having an open upper surface. The accommodating member 70 may include an internal accommodating part that can be lifted therein, and the internal accommodating part may also be formed in a basket shape. It can be defined as a drawer device including the receiving member and the inner receiving unit.

That is, the drawer device may include an external accommodating part and an internal accommodating part 71 , and the external accommodating part may be drawn out in the front-rear direction, and the internal accommodating part 71 may be configured to be lifted up and down in the vertical direction. Draw-out of the external accommodating part and raising/lowering of the internal accommodating part 71 may be continuously performed by the driving assembly 40 .

The internal accommodating part 71 has a size that can be accommodated inside the accommodating member 70 and preferably has an outer surface of the internal accommodating part 71 in contact with the inner surface of the internal accommodating part 71 . can be formed. In addition, the height of the inner accommodating part 71 may be formed to be lower than the height of the accommodating member 70 .

The inner accommodating part 71 has a structure that can be lifted up and down, and for this purpose, elevating guides 711 extending in the vertical direction are formed on both left and right sides of the accommodating member 70 . The lower pulley 462 may be coupled to the inner accommodating part 71 through the elevating guide 711 , and the inner accommodating part 71 may be moved up and down by the vertical movement of the lower pulley 462 . can The internal accommodating part 71 can be lifted up and down in a state in which the accommodating member 70 is fully withdrawn, so that when the internal accommodating part 71 is raised and lowered, it does not interfere with the components in the cabinet.

Rack parts 133 may be formed on both left and right wall surfaces of the lower storage space 53 for the storage member 70 to be pulled out and inserted. The rack part 133 is formed to be elongated in the front-rear direction, and as the pinion 42 of the driving assembly 40 moves along the rack part 133 , the accommodating member 70 can be drawn in and out.

The driving assembly 40 may include a motor 41 provided in the housing member 70 , a pinion 42 rotated by the motor 41 , and the clutch 44 . In addition, the clutch 44 may selectively transmit the power of the motor 41 to the pinion 42 , and may be connected to the wire 43 to wind the wire 43 .

The wire 43 may be connected to the clutch 44 , the upper pulley 461 , and the lower pulley 462 , and depending on whether the wire 43 is wound by the rotation of the clutch 44 , the inner The accommodating part 71 may be raised and lowered. Meanwhile, any one of the above-described embodiments may be applied to the specific structure and operation of the driving assembly 40 .

When a user inputs a manipulation through the manipulation unit 612 , the accommodating member 70 can be automatically withdrawn by driving the driving assembly 40 , and when the accommodating member 70 is completed, the accommodating member 70 is continuously pulled out. The inner accommodating part 71 rises.

In addition, after accommodating food in the raised internal storage unit 71 , the storage member 70 is automatically drawn out by driving the driving assembly 40 when an operation is input through the operation unit 612 again. The inner accommodating part 71 is lowered, and when the lowering of the inner accommodating part 71 is completed, the accommodating member 70 is continuously introduced. In addition, after the insertion of the storage member 70 is completed, the lower door 62 may be closed to shield the interior space and the storage member 70 .

Claims (20)

an external accommodating part that forms a space with an open upper surface and is drawn out and inserted into the inside of the cabinet;
a pull-out guide provided on the outside of the external accommodating part and for guiding the pull-out and entry of the external accommodating part;
an inner accommodating part which forms at least a part of a bottom surface of the accommodating space in the interior of the external accommodating part and is raised and lowered;
A drive assembly coupled to the pull-out guide and the inner accommodating part, the driving assembly providing power for pulling-out and elevating the external accommodating part; includes,
The drive assembly is
motor;
a drive shaft connected to the rotation shaft of the motor;
a pinion connected to the drive shaft and rotated together with the drive shaft, the pinion being moved along the pull-out guide;
a clutch provided on the drive shaft to selectively transmit the rotational force of the motor to the pinion; and
a wire connecting the clutch and the internal accommodating part, the wire wound around the clutch to elevate the internal accommodating part;
The drive shaft is
a first drive shaft connected to the rotation shaft of the motor;
and a second drive shaft connected to the pinion,
The clutch selectively connects the first drive shaft and the second drive shaft to selectively transmit the rotational power of the motor to the second drive shaft.
The method of claim 1,
The drawer device, characterized in that the inner accommodating portion is formed in a basket shape with an open upper surface.
The method of claim 1,
The drawer device, characterized in that the upper and lower guide for guiding the vertical movement of the inner storage unit is formed in the external storage unit.
The method of claim 1,
The pull-out guide is provided on the inner surface of the cabinet,
The drive assembly is a drawer device, characterized in that provided in the external receiving portion.
The method of claim 1,
The wire is
The drawer device according to claim 1, wherein the inner accommodating part is lifted and wound around the clutch in a state in which power transmission to the pinion is blocked.
The method of claim 1,
The second drive shaft,
Drawer device, characterized in that spaced apart on the same extension line as the first drive shaft.
7. The method of claim 6,
The first drive shaft includes a first screw thread inserted into and coupled to the screw coupling part inside the clutch,
The second drive shaft,
a non-engagement part inserted into the clutch at the end of the second drive shaft and not engaged with the clutch;
and a second thread formed toward the pinion at the end of the non-coupled part and coupled to the screw-coupled part,
The clutch transmits power to the pinion when it is engaged with the second screw thread, and when the clutch is completely moved to the first driving side, an uncoupled part is inserted inside the clutch to transmit power to the pinion Drawer device, characterized in that to block.
7. The method of claim 6,
The first drive shaft includes a first screw thread inserted into and coupled to the screw coupling part inside the clutch,
The second drive shaft,
a rotating part inserted into the clutch at the end of the second drive shaft but not coupled to the clutch;
It extends from the end of the rotating part toward the pinion and includes a connecting part having a polygonal cross-sectional shape having the same shape as the opening of the clutch end,
The clutch transmits power to the pinion in a state coupled to the connection part, and when the clutch is completely moved to the first driving side, a rotating part is inserted inside the clutch to block power transmission to the pinion Drawer device, characterized in that.
7. The method of claim 6,
The first drive shaft is
a first screw thread inserted into and coupled to the screw coupling part inside the clutch;
It is provided on the first drive shaft and includes a restraining member that is moved according to the movement of the clutch,
The second drive shaft includes a constraint that is selectively coupled to the constraint member according to the movement of the constraint member,
The clutch transmits power to the pinion in a state in which the restraining member is restrained by the restraining unit, and the clutch is moved to contact the restraining member so that the restraining member is released from the restraining unit to the pinion. Drawer device, characterized in that blocking the power transmission.
an external accommodating part that forms a space with an open upper surface and is drawn out and inserted into the inside of the cabinet;
a pull-out guide provided on the outside of the external accommodating part and for guiding the pull-out and entry of the external accommodating part;
an inner accommodating part which forms at least a part of a bottom surface of the accommodating space in the interior of the external accommodating part and is raised and lowered;
A drive assembly coupled to the pull-out guide and the inner accommodating part, the driving assembly providing power for pulling-out and elevating the external accommodating part; includes,
The drive assembly is
motor;
a motor gear rotated by the shaft of the motor;
a drive shaft extending parallel to the axis of the motor;
a driving gear provided on the driving shaft and selectively connected to the motor gear to transmit power to the driving shaft;
a pinion provided on the drive shaft and rotated together with the drive shaft, the pinion being moved along the pull-out guide;
a clutch disposed slidably along the drive shaft and selectively transmitting the rotational force of the motor to the pinion; and
and a stopper formed of a metal material on one side of the clutch and moving the clutch by a magnet provided in the pull-out guide.
11. The method of claim 10,
The motor gear includes a first motor gear and a second motor gear spaced apart on the shaft of the motor,
The drive gear is spaced apart on the drive shaft and includes a first drive gear rotated together with the pinion and a second drive gear rotated together with the clutch,
According to the movement of the clutch, the first motor gear is coupled to the first driving gear, and the second motor gear is coupled to the second driving gear.
12. The method of claim 11,
The drive shaft is
a first driving unit having a polygonal cross-sectional shape and mounted with the first driving gear to rotate the driving shaft together by the driving force of the motor;
and a second driving unit having a circular cross-sectional shape and allowing the second driving gear and the clutch to rotate independently of the driving shaft.
11. The method of claim 10,
The magnet is a drawer device, characterized in that it is provided at a point of the pull-out guide corresponding to the position of the clutch in a state in which the external receiving part is completely withdrawn.
14. The method of claim 13,
The magnet is an electromagnet,
In a state in which the external storage unit is drawn out, power is applied to generate a magnetic force,
Drawer device, characterized in that the magnetic force is extinguished by shutting off the power when the lowering of the inner receiving part is completed.
15. The method of claim 14,
The drawer device, characterized in that the stopper is provided with an elastic member for elastically supporting the motor gear and the driving gear to return to the original combined position.
a cabinet in which a storage space is formed; and
It includes a drawer device provided in the storage space,
The drawer device,
an external accommodating part provided inside the storage space so as to be able to be drawn in and out, and forming a space with an open upper surface;
a pull-out guide provided on the outside of the external accommodating part and for guiding the pull-out and entry of the external accommodating part;
an inner accommodating part which forms at least a part of a bottom surface of the accommodating space in the interior of the external accommodating part and is raised and lowered;
A drive assembly coupled to the pull-out guide and the inner accommodating part, the driving assembly providing power for pulling-out and elevating the external accommodating part; includes,
The drive assembly is
motor;
a drive shaft connected to the rotation shaft of the motor;
a pinion connected to the drive shaft and rotated together with the drive shaft, the pinion being moved along the pull-out guide;
a clutch provided on the drive shaft to selectively transmit the rotational force of the motor to the pinion; and
and a wire that connects the clutch and the internal accommodating part, and is wound around the clutch to elevate the internal accommodating part,
The drive shaft is
a first drive shaft connected to the rotation shaft of the motor;
and a second drive shaft connected to the pinion,
The clutch selectively connects the first drive shaft and the second drive shaft to selectively transmit the rotational power of the motor to the second drive shaft.
17. The method of claim 16,
The refrigerator provided with a drawer device, characterized in that the cabinet includes a door that opens and closes the storage space and is coupled to the external storage unit to be pulled out and taken out together.
17. The method of claim 16,
A door for opening and closing the storage space by rotation and shielding the external storage unit is mounted on the opened front side of the cabinet,
The door is a refrigerator with a drawer device, characterized in that the door is opened and closed independently of the drawer in and out of the external storage unit.
17. The method of claim 16,
The withdrawal guide is provided on both side walls of the storage space,
The drive assembly is a refrigerator provided with a drawer device, characterized in that provided in the external receiving unit.
17. The method of claim 16,
The withdrawal guide is provided on both sides of the external receiving part,
The drive assembly is a refrigerator provided with a drawer device, characterized in that provided on both side walls of the storage space.

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